Lex Fridman Podcast - #269 – Lee Cronin: Origin of Life, Aliens, Complexity, and Consciousness
Episode Date: March 11, 2022Lee Cronin is a chemist at the University of Glasgow. Please support this podcast by checking out our sponsors: - Paperspace: https://gradient.run/lex to get $15 credit - Athletic Greens: https://athl...eticgreens.com/lex and use code LEX to get 1 month of fish oil - Notion: https://notion.com/startups to get up to $1000 off team plan - Blinkist: https://blinkist.com/lex and use code LEX to get 25% off premium - Onnit: https://lexfridman.com/onnit to get up to 10% off EPISODE LINKS: Lee's Twitter: https://twitter.com/leecronin Lee's Website: https://www.chem.gla.ac.uk/cronin/ Chemify's Website: https://chemify.io 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 (08:31) - Life and chemistry (21:56) - Self-replicating molecules (32:19) - Origin of life (48:45) - Life on Mars (53:49) - Aliens (1:00:30) - Origin of life continued (1:07:24) - Fermi Paradox (1:17:04) - UFOs (1:25:25) - Science and authority (1:31:28) - Pickle experiment (1:34:23) - Assembly theory (2:17:22) - Free will (2:28:37) - Cellular automata (2:52:08) - Chemputation (3:09:23) - Universal programming language for chemistry (3:22:34) - Chemputer safety (3:35:15) - Automated engineering of nanomaterials (3:44:15) - Consciousness (3:53:48) - Joscha Bach (4:05:04) - Meaning of life
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The following is a conversation with leak Ronan, a chemist from University of Glasgow,
who is one of the most fascinating, brilliant, out-of-the-box thinking scientists I've ever spoken to.
This episode was recorded more than two weeks ago, so the war in Ukraine is not mentioned.
I have been spending a lot of time each day talking to people in Ukraine and Russia.
I have family, friends, colleagues, and loved ones in both
countries.
I will try to release a solo episode on this war, but I've been failing to find the
words that make sense of it for myself and others.
So I may not.
I ask for your understanding no matter which path I take.
Most of my time is spent trying to help as much as I can privately. I'm talking to people
who are suffering, who are angry, afraid. When I returned to this conversation with Lee,
I couldn't help but smile. He's a beautiful, brilliant, and hilarious human being.
He's basically a human manifestation of the mad scientist Rick Sanchez from Rickam
Morty. I thought about quitting this podcast for a time, but for now at least I'll keep going.
I love people too much. You the listener. I meet folks on the street or when I run.
You save you kind words about the podcast and we talk about life, the small things and
the big things. All of it gives me hope. People are just amazing. You are amazing. I ask for
your support, wisdom and patience as I keep going with this silly little podcast, including through some difficult conversations.
And hopefully, many fascinating and fun ones too.
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conversation with Lee Cronin. How do you think life originated on earth?
And what insights does that give us about life?
If we go back to the origin of earth and you think about maybe 4.6, 4.5 billion years ago, planet was quite hot,
there was a limited number of minerals, there was some carbon, some water, and I think that
maybe it's a really simple set of chemistry that we really don't understand. So that means
you've got a finite number of elements that are going to react very simply with one another,
and out of that mess comes a cell. So literally
sand turns into cells and it seems to happen quick. So what I think I can say with some
degree of, I think, not certainty, but curiosity, genuine curiosity is a life happened fast.
Yes, so when we say fast, this is a pretty surprising fact, and maybe you can actually correct me in
elaborate, but it seems like most, like 70 or 80% of the time that earth has been around
has been life on it, like some very significant percentage. So when you say fast, like the
slow part is from single cell or from bacteria to some more complicated organism, it seems
like most of the time that Earth has been around,
it's been single cell or like very basic organisms
like a couple of billion years.
But yeah, you're right.
That's really, I recently kind of revisited our history
and saw this.
And I was just looking at the timeline, wait a minute.
Like how did life just spring up so quickly?
Like really quickly. That makes me think that it really wanted to, like put another way,
it's very easy for life to spring. Yeah, I agree. I think it's much more inevitable.
And I think I tried to kind of not provoke, but try and push chemists to think about,
because chemists are part essential to this problem, right?
Understanding the origin of life on earth at least because we're made of chemistry.
But I wonder if the origin of life on a planet also, the emergence of life on planet is
as common as the formation of a star.
And if you start framing it in that way, it allows you to then look at the universe
slightly differently, because, and we can get into this, I think, in quite some detail, but I think
I, to, to come back to your question, I have a little idea of how life got started, but I know
it was simple, and I know that the process of selection had to occur before the biology was established. So that selection built the
framework from which life kind of grew in complexity and capability and functionality and autonomy.
And I think these are all really important words that we can unpack over the next while.
Can you say all the words again? So you said selection. So natural selection,
the original AB testing. And so, and then complexity, and then the degree of autonomy and sophistication.
Because I think that people misunderstand what life is. Some people say that life is a cell,
and some people that say that life is a virus, or is a, you know, an on-off switch.
I don't think it's that life is the universe developing a memory and the laws of physics and the
way, well there are no laws of physics. Physics is just memory-free stuff, right? So there's only a
finite number of ways you can arrange the fundamental
particles to do the things. Life is the universe developing a memory. So it's like
sewing a piece of art slowly and then you can look back at it. So so there's a
stickiness to life.
It's like universe doing stuff.
And when you say memory, it's like there's a stickiness to a bunch of the stuff that's
building together.
Yeah.
So like you can in a stable way like trace back the complexity and that tells a coherent
story.
Yeah.
And I think yeah.
Okay. That's by the way, very poetic.
Beautiful.
Life is the universe developing a memory.
Okay, and then there's autonomy,
you said in complexity, we'll talk about,
but it's a really interesting idea
that selection preceded biology.
Yeah, I think, so what,
first of all, what is chemistry?
Like the sand still calm as chemistry.
Sure.
I mean, as a chemist, the card carrying chemist, if I'm allowed a card, I don't know.
I don't know what I am most.
What is the card made of?
What's the chemical composition of the card?
Yeah.
So what is chemistry?
Well, chemistry is the thing that happens when you bring electrons together
and you form bonds. So bonds, or I say to people when they talk about life elsewhere, and I just say
whether there's bonds, there's hope, because bonds allow you to get heterogeneity, they allow you to
record those memories, or at least on Earth, you could imagine a Stanislaus Lemtripe world where you might have life emerging
or intelligence emerging before life.
That may be something on in like Solaris or something,
but to get to selection,
if atoms can combine, form bonds,
those atoms can bond to different elements
and those molecules will have different identities
and interact with each other differently.
And then you can start to have some degree
of causation or interaction and then selection
and then existence.
And then you go up the path of complexity.
And so at least on Earth, as we know it,
there is a sufficient pool of available chemicals to start
create searching that combinatorial space of bonds. So, okay, this is a really
interesting question. Let's lay it out. So bonds, almost like cards. We say
there's bonds, there is life, there's intelligence, there's consciousness. And when you just made me realize is
those can emerge or let's put bonds aside, those can emerge in any order.
That's that's really brilliant. So intelligence can come before life. It's like
panpsychists believe that consciousness, I guess, comes before
life and before intelligence. So consciousness permeates all matters, some kind of fabric
of reality. Okay, so within this framework, you can kind of arrange everything, but you
need to have the bonds that precedes everything else. Oh, and the other thing is selection. So like
the mechanism of selection, that could proceed. So you couldn't that proceed bonds to whatever
the health selection is.
So I would say that there is an elegant order to it that bonds allow selection, allows
emergence of life, allows the emergence of multi-cellarity and then more information processing,
building state machines all the way up. However, you could imagine a situation if you had, I don't know,
a neutron star or a sun or what, a ferromagnetic loops interacting with one another and these oscillators
building state machines and these state machines reading something out in the environment. Over time,
these state machines would be able to literally record what happened
in the past and sense what's going on in the present and imagine the future.
However, I don't think it's ever going to be with within a human comprehension,
that type of life.
I wouldn't count it out because, you know, whenever you say, I know in science,
whenever I say something's impossible, I then wake up next day and say,
no, that's actually wrong.
I mean, there are some limits, of course.
I don't see myself traveling fast and light anytime soon.
But...
But I require a sense that's possible.
So he will say you're up.
Sure, but I'm an experimentalist as well.
So one of my, I have two superpowers.
And my stupidity, and I don't mean that is,
I'm like, absolutely completely witness, but I mean my ability that is, you know, I'm like absolutely completely
witness, but I mean my ability to kind of just start again and ask the question.
And then do it with an experiment.
I always want to be a theoretician growing up, but I just didn't have the intellectual
capability, but I was able to think of experiments in my head.
I could then do in my lab or in the, you know, when I was a child outside, and then those experiments in my head and then
outside reinforced one another.
So I think that's a very good way of kind of grounding the science, right?
Well, that's the nice way to think about theoreticians is there are just people who run experiments
in their head.
I mean, it's exactly what Einstein did, right?
But you're also capable of doing that in the head, in your head, inside your head, and in the real world and the connection between the two, is when you first discovered your
superpowers, stupidity. I like it. Okay. What's the second superpower? Your accent or
that? Well, I don't know. I am genuinely curious. So I have a, you know, like everybody,
ego problems, but my curiosity is bigger than my ego. So as long as that happens, I can, I can, I can, that is awesome.
That is so powerful. You're just dropping some powerful lines. So curiosity is bigger than
ego. That's something I have to think about because you always struggle about the role
of ego in life. And that's, that's so nice to think about, don't think about the size of ego, the absolute size
of ego, think about the relative size of ego to the other, the other horse is pulling
at you.
And if the curiosity went as bigger, then ego will do just fine and make you fun to talk
to.
Anyway, so those are the two superpowers.
How do those connect to natural selection or in selection and bonds?
And I forgot already life and consciousness.
So we're going back to selection and universe and origin of life on earth. I mean
Selection is a full I'm convinced that selection is a force in the universe
So not mean not a fundamental force, but a but a directing where there is a directing force because existence although, although existence appears to be the default,
the existence of what, why does, we can get to this later, I think, but it's amazing that
discrete things exist. And you see this cup, it's not the sexiest cup in the world,
but it's pretty functional. The complexity of this cup isn't just in the object.
It is literally the lineage of people making cups and recognizing that,
seeing that in their head making an abstraction of a cup and then making a different one.
I wonder how many billions of cups have come before this one,
and that's a process of selection and existence.
The only reason the cup is still used is quite useful.
I like the handle, you know, it's convenient
so I don't die on key hydration.
And so I think we are missing something fundamental
in the universe about selection.
And I think what biology is, is a selection amplifier.
And that this is where autonomy comes in.
And actually, I think that how humanity is going to humans and
Autonomous robots or whatever we're going to call them in the future will will supercharge that even further
So selection is happening in the universe, but if you look in the asteroid belt
selection if objects are being kicked in and out the asteroid belt
Those trajectories are quite complex. You don't really look at that as productive selection because it's not doing anything to improve its function.
But is it? The asteroid belt has existed for some time. So there is some selection going on, but the functionality is somewhat limited on Earth. At the formation of Earth, interaction of chemicals and molecules in the environment gave selection and then things could happen because you could think about in chemistry
We could have an infinite number of reactions happen, but they don't all have all the reactions that allowed to happen don't happen why because of energy barriers.
So there must be some things called catalysts out there or there are bits of minerals that when two molecules get together
in that mineral, it lowers the energy barrier for the reaction, and so the reaction is promoted.
So, suddenly you get one reaction over another of series of possibilities occurring that makes
a particular molecule, and this keeps happening in steps. And before you know it, these,
almost these waves as discrete reactions work together together and you start to build a machinery
that is run by existence. So as you go forward in time, the fact that the molecules, the
bonds are getting, they're more bonds in a molecule, there's more function, there's
more capability for this molecule to interact with other molecules, to redirect them. It's
like a series of little, and I don't want to use this term too much, but it's almost
thinking about the simplest von Neumann constructor, the simplest molecule that could build a more
complicated molecule, the builder more complicated molecule.
And before you know it, when that more complicated molecule can act on the causal chain that's
produced itself and change it, suddenly you start to get towards some kind of autonomy and that's where life I
think emerges in earnest.
Every single word in the past few paragraphs, let's break those apart.
But who's Von Neumann?
What's the constructor, the closing of the loop that you're talking about?
The molecular starts becoming becoming, I think you
said, the smallest volume, the noise and constructor, the smallest, the minimal. So what do all
those things mean? And what is, are we supposed to imagine when we think about the smallest
volume and constructor?
So, John von Neumann is a real hero, actually not just me, but many people, I think computer
science and physics.
He was an incredible intellect, who probably solved a lot of the problems that we're working
on today and just forgot to write them down.
And I'm not sure if it's John von Neumann or Johnny, as I think his friends called him,
but I think he was Hungarian.
Mathematician came to the US.
And basically he got, was involved in the Manhattan project and developing computation
and came up with all sorts of ideas.
And I think it was one of the first people to come up with cellular automata.
And but he, I don't know this little fact.
I think so.
I think so.
Well, anyway, if he didn't come up with it, he probably did come up with
engine right down. There was a couple of people did it at the same time and then Conway obviously
took it on and then Wolfram loves C.A.s. there is his fabric of the universe. And what I think he
imagined was that he wasn't satisfied and this may be incorrect recollection, but so a lot of what
I say is going to be kind of, you know, just way out of my you're late. You're just part of the universe
creating its memory, designing exactly. Yeah, rewriting history.
Rewriting. Exactly.
Imperfectly. So, but what I mean is I think he would like this idea of thinking about
how could a
Turing machine literally build itself without a cheering machine?
It's like literally how did state machines emerge?
I think that von Neumann constructors,
he wanted to conceive of a minimal thing,
or a tonnemer, that could build itself,
and what would those rules look like in the world?
That's what a von Neumann constructor looked like.
It's a minimal hypothetical object that could build itself, self replicate.
And I'm really fascinated by that
because I think that although it's probably not
exactly what happened, it's a nice model
because it's chemist.
If we could go back to the origin of life
and think about what is a minimal machine
that can get structured randomly.
So like with no prime mover,
with no architect, it just extends. So random stuff bumping in together and you make this first
molecule. So you have molecule A. And molecule A interacts with another random molecule B and they
get together and they realize by working together they can make more of themselves.
But then they realize they can mutate so they can make A B prime. So A B prime is different to A B and then A B prime can then act back where A and B will be created.
And slightly not that causal chain and and make AB prime more
available or learn more.
So that's the closing the loop part.
Closing the loop part, got it.
It feels like the mutation part is not that difficult.
It feels like the difficult part
is just creating a copy of yourself as step one.
It seems like one of the greatest inventions
in the history of the universe is the first molecule that figured out holy shit, I can create a copy of myself.
How hard is that?
I think it's really, really easy.
Okay, I did not expect that.
I think it's really, really easy.
Well, let's take a step back. I think replication, replicating molecules are rare.
But if you say, I think I was saying,
I've probably gotten to trouble on Twitter,
those were trying to work,
there's about more than 18 miles of water in there.
So one mole of water, 6.02, two times 10 to the 23 molecules.
That's about the number of stars in the universe,
I think, of the order.
So there's three universe worth, but between one of...
Oh, so many corrected giant order.
Yeah, as with, I'm always being corrected.
It's a great fact.
But there's a lot of molecules in the water.
Yeah.
And so, there's a lot of, so although it's for you and me, really hard to conceive of,
if existence is not the default for a long period of time,
because what happens is a molecule gets degraded.
So, so much of the possibilities in the universe are just broken back into atoms. So, you have
this kind of destruction of the molecules for our chemical reactions. So, you only need
one or two molecules to become good at copying themselves, for them suddenly to then take
resources in the pool and start to grow. And
so then replication actually over time, when you have bonds, I think is much simpler and
much easier. And I even found this in my lab years ago, I had one of the reasons I started
doing inorganic chemistry and making rust, making a bit of rust based on a thing called
molybdenum. Molybdenum oxide, is this molybdenum oxide very simple,
but when you add acid to it and some electrons, they make these molecules, you just cannot possibly
imagine, would be constructed big gigantic wheels of 154 molybdenum atoms in a wheel, or a icosododeca
Hadron, 132 molybdenum atoms, all in the same pot. And I realized, when I, and I just finished experiments two years ago, I've just published
a couple of papers on this, that they're actually, there is a random small molecule with 12 atoms
in it that conform randomly, but it happens to template its own production.
And then by chance, it templates the ring, just an accident, just like just a absolute accident.
And that ring also helps make the small 12 m. And so you have what's called an auto catalytic
set where A makes B and B helps make A an vice versa. And you then make this loop. So there's a bit like these,
they all work in synergy to make this chain of events that grow.
And it doesn't take a very sophisticated model to show that
if you have these objects are competing and then collaborating to help one another build,
they just grow out of the mess.
And although they seem improbable,
they are improbable, in fact impossible, in one step.
There's multiple steps.
This is when the blind people look at the blind watchmaker argument
and you're talking about how could a watch spontaneously emerge?
Well, it doesn't.
It's a lineage of watches and cruder devices
that a bootstrapped onto one another. It doesn't. It's a lineage of watches and crude devices that the couple of boots strapped
onto one another.
Right. So it's very improbable, but once you get that little discovery, like with the wheel
and fire, it just gets explodes in because it's so successful at explode. This is basically selection.
So this templating mechanism that allows you
to have a little like blueprint for yourself,
how you go through different procedures
is to both copies of yourself.
So I, in chemistry somehow, it's possible to imagine
that that kind of thing is easy to spring up.
In more complex organisms, it feels like a different thing and much more complicated.
We're having multiple abstractions of the birds and the bees conversation here, but with
human, sorry, with complex organisms, it feels like difficult to have reproduction, that's going to get coped out. I'm going to make fun of that. It's
difficult to develop this idea of making copies yourself or no. Because that seems like
a magical idea for life to, wow. That feels like very necessary for what selection is, for what evolution is,
but then if selection proceeds all this, then maybe these are just like echoes of the selecting
mechanism at different scales.
Yeah, that's exactly it. So selection is the default in the inverse, if you want to.
And what happens is that life, the solution that life has got on Earth, life on
Earth, biology on Earth is unique to Earth, we can talk about that. And that was really
hard for it, but that is a solution that works on Earth, the ribosome, the fundamental
machine that is responsible for every life, you know, every cell on earth or whatever, wherever it is in the ficking of life.
That is an incredibly complex object,
but it was evolved over time and it wasn't involved in a vacuum.
And I think that once we understand that selection can occur
without the ribosome,
but what the ribosome does,
it's a phase transition in replication.
And I think that that, and also technology,
that is probably much easier to get to than we think.
Why do you put the ribosome as a central part
of living organisms on Earth?
It basically is a combination of two different polymer systems.
So RNA and peptide.
So the RNA world, if you like, gets transmitted and builds proteins and the proteins are responsible
for all the catalysis. The majority of the catalysis goes on in the cell. No ribosome, no proteins,
no decoding, no evolution. So ribosome is looking at the action. You don't put like the RNA itself as the critical thing.
Like, information, you put action as the most important thing.
Yeah, I think the actual molecules that we have in biology right now,
entirely contingent on the history of life on it.
If they could, there are so many possible solutions.
And this is where chemistry got itself into origin,
of life chemistry gets itself into a bit of a trap.
Yeah, let me interrupt you there.
You've tweeted, you're gonna get,
I'm gonna set your tweets like it's Shakespeare.
Okay.
It's surprising you haven't got a cancel on Twitter yet.
It's your brilliance once against Aizu.
I'm just kidding.
There's, you like to have a little bit of fun on Twitter.
You've tweeted that quote,
origin of life research is a scam.
So if this is Shakespeare, can we analyze this word? You've tweeted that quote, origin of life research is a scam.
So if this is Shakespeare, can we analyze this word? Why is the origin of life research a scam?
Aren't you kind of doing origin of life research?
Okay, it was tongue in cheek,
but yeah, I think and I meant it as tongue in cheek.
I am not doing the origin of life research.
I'm trying to make artificial life. And I also want to bound the likelihood doing the origin of life research. I'm trying to make artificial life.
And I also want to bound the likelihood of the origin
of life on Earth, but more importantly,
to find origin of life elsewhere.
But let me directly address the tweet.
There are many, many good chemists out there
doing origin of life research, but I want to nudge them.
And I think the brilliant, there's no question
the chemistry they are doing, their motivation
is great.
So what I meant by that tweet is saying that maybe they're making assumptions about saying
if only I could make this particular type of molecule, say this RNA molecule or this phosphodiester
or this other molecule, it's going to somehow unlock the origin of life.
And I think that origin of life has been looking at this for a very long time.
And whilst I think it's brilliant to work out how you can get to those molecules, I think
that chemistry and chemist doing origin of life could be nudged into doing something
even more profound. And so the argument I'm
making, it's a bit like right now, let's say, I don't know, the first Tesla that makes
its way to, I don't know, into a new country in the world. Let's say, I say there's a country
X that has never had a Tesla before and they get the Tesla.
Russia. And they take the test, and what they do is they take the Tesla apart and say,
we want to find the origin of cars in the universe and say, okay, how did this form and how did
this form?
And they just randomly keep making till they make the door, they make the wheel, they make
the steering column and all this stuff.
And they say, oh, that's the route.
That's the way cars emerge on Earth.
But actually, we know that there's a causal chain of cars going right back to Henry Ford
and the horse and carriage. And before that, maybe, you know, where people were using wheels. And I think that obsession with
the identities that we see in biology right now are giving us a false sense of security about what
we're looking for. And I think that origin of life chemistry is in danger
of not making the progress that it deserves
because the chemists are doing this,
the field is exploding right now,
there is amazing people out there,
young and old doing this.
And there's deservedly so more money going in.
I used to complain,
there's more money being spent searching for the Higgs Boson
that we know exists than the origin of life.
Why is that?
We understand the origin of life, we're going to actually work at what life is, and we're
going to be at a bound to likelihood of finding life elsewhere in the universe.
And most important for us, we are going to know or have a good idea of what the future
of humanity looks like.
We need to understand that although we're precious, we're not the only life forms in the universe.
Or that's my very strong impression. I have no data for that. It's just right now our belief.
And I want to turn that belief into more than a belief by experimentation.
But I coming back to the scam, the scam is if we just make this RNA, we've got this, you know, this, this fluke event, we know how that's simple. Let's
make this phosphodiester, or this make ATP or ADP, we've got that part nailed. Let's now
make this other molecule, another molecule, and how many molecules are going to be enough.
And then the reason I say this is when you go back to Craig Venter, when he invented He invented his life form, Cyndia. This minimal plasma, it's a myo plasma,
something I don't know the name of it,
but he made this wonderful cell and said,
I've invented life, not quite.
He fact-simileed the genome from this entity
and made it in the lab or the DNA,
but he didn't make the cell.
He had to take an existing cell that has a causal cengo and all the way back to Luka,
and he showed when he took out the genes and put in his genes, synthesized, the cell
could be up.
But it's remarkable that he could not make a cell from scratch.
And even now today, synthetic biologists cannot make a cell from scratch
because there's some contingent information
embodied outside the genome in the cell.
And that is just incredible.
So there's lots of layers to the scam.
Well, let me then ask the question,
how can we create life in a lab from scratch?
What have been the most promising attempts at creating life in a lab from scratch?
Has anyone actually been able to do it?
Do you think anyone will be able to do it in the near future if they haven't already?
Yeah, I think that nobody has made life in the lab from scratch.
Lots of people would argue that they have made progress.
The Craig Van, I think the synthesis of a synthetic genome,
milestone in human achievement, brilliant.
Yeah, can we just walk back and say,
what would you say from your perspective,
one of the world experts in exactly this area,
what does it mean to create life from scratch,
where if you sit back,
whether you do it or somebody else does it, it's like, damn, this is, we just created life.
Well, what I would, I can tell you what I would expect, I would like to be able to do, is to
go from sand to cells in my lab and I'm
going to explain what sand is.
Yeah, just in organic stuff.
Like basically just so sand is just silicon oxide with some other ions in it, maybe some
inorganic carbon, some carbonates, just basically clearly dead stuff you could just grind rocks
into sand.
And it would be what, in a vacuum,
so they could remove anything else
that could possibly be like a shadow of life
that can assist in the chemical.
You could do that.
You could do insist and say,
look, I'm gonna take, not just in organic,
I want some more, I want to cheat and have some organic,
but I want inorganic organic,
and I'll explain the play on words in a moment. So I would like to basically put into a world, say, completely, you know,
a synthetic world, if you like a closed world, put some inorganic materials and just literally
add some energy in some form, be it lightning or heat, UV light and run this thing in cycles
over time and let it solve the search problem.
I see the origin of life as a search problem in chemical space. And then I would wait,
literally wait for a life form to crawl out the test tube. That's the joke I tell my group.
Literally wait for a very, don't worry, it's going to be very feeble, it's not going to take
over the world. There's ways of effectively containing it. In the Slaswards.
Indeed, indeed, indeed.
But I, you know, this is being recorded, right?
It will not make you look good once it crawls out of the lab
and destroys all human civilization.
But yes, but there is very good,
there's a very good thing you can do to prevent that.
For instance, if you put stuff in your world,
which isn't earth abundant,
so let's say we make life based on molybdenum
and it escapes, it would die immediately
because there's not enough molybdenum in the environment.
So we can do responsible life,
or as I fantasized with my research group on our wayday
that would go in, I think it's actually morally,
if we don't find, if you're find, until humanity finds life in the universe,
this is going on the tangent,
it's our moral obligation to make origin of life bombs.
Identify dead planets and bomb them
with our origin of life machines and make them alive.
I think it is our moral obligation to do that.
Some people might argue with me about that,
but I think that we need more life in the universe.
And then we kind of forget, did it and then come back.
So where did you come from?
But coming back to the what I'd expect.
So I just say, are you back?
It's I think this is what's again a Rick and Morty episode.
It definitely definitely all Rick and Morty all the way down.
So we imagine we have this pristine experiment and everything is, you know, sanitized
and we put in inorganic materials and we have cycles with them day night cycles up down whatever
and we look for evidence of replication and evolution over time and that's what the experiment
should be. Now are there people doing this in the world right now? There are a couple of
there's some really good groups doing this. There's some really interesting scientists doing this in the world right now, there are a couple of, there's some really good groups doing this, there's some really interesting scientists doing this around the world.
They're kind of, perhaps, too much associated with the scam, and so they're using molecules
that are already, we're already invented by biology, so there's a bit of replication
built in, but I still think the work they're doing is amazing.
But I would like people to be a bit freer and say,
let's just basically shake a load of sand in a box
and wait for life to come out,
because that's what happened on Earth,
and so that we have to understand that.
Now, how would I know I've been successful?
Well, because I'm not obsessing
with what molecules are in life now,
I would wager a vast quantity of money. I'm not very rich, so just be a few dollars, but for me, I feel that the solution space
will be different. So the genetic material will be not RNA. The proteins will not be what
we think. The solutions will be just completely different.
And it might be, and it will be very feeble,
because that's the other thing we should be able to show
fairly robustly that even if I did make
or someone did make a new life form in the lab,
it would be so poor that it's not gonna leap out.
It is the fear about making a lethal life form
in the lab from scratch is similar to us imagining that we're going to make the Terminator Boston Dynamics tomorrow.
The problem is, we don't communicate that properly.
I know you yourself, very, you explain this very well.
There is not the AI Catastroph coming.
We're very far away from that. That doesn't mean we should ignore it. you explain this very well. There is not the AI Catastroph coming.
We're very far away from that. That doesn't mean we should ignore it.
Same with the origin of life Catastroph,
it's not coming anytime soon.
We shouldn't ignore it,
but we shouldn't let that fear stop us from doing this.
But this is a much, much longer discussion
because there's a lot of details there.
I would say there is potentials for catastrophic events
to happen in much dumber ways.
In AI space, there's a lot of ways to create
like social networks are creating a kind of accelerated
set of events that we might not be able to control.
The social network of virality in the digital space
can create mass movements of ideas that can then, if times are tough,
create military conflicts and all those kinds of things.
But that's not super intelligent AI.
That's an interesting at scale application of AI.
If you look at viruses, viruses are pretty dumb, but at scale, their application is pretty
detrimental.
And so origin of life, much like all of the kind of virology, you know, the very contentious
word of gain of function research and virology, sort of like research on viruses, messing
with them genetically,
that can create a lot of problems if not done well.
So we have to be very cautious.
So there's a kind of, whenever you're ultra cautious
about stuff in AI or in a virology and biology,
it borders on cynicism, I would say,
where it's like everything we do is going to turn
out to be destructive and terrible, so I'm just going to sit here and do nothing.
Okay, that's a possible solution, except for the fact that somebody is going to do it.
It's science and technology progresses, so we have to do it in an ethical way, in a good way, considering in a transparent way,
in an open way, considering all the possible positive trajectories that could be taken
and making sure as much as possible that we walk those trajectories.
So yeah, I don't think Terminator is coming, but a totally unexpected version of Terminator
may be around the corner.
Yeah, it might be here already.
Yeah, so I agree with that.
And so going back to the origin of life discussion,
I think that in synthetic biology right now,
we have to be very careful about how we edit genomes
and edit synthetic biology to do things.
So that's kind of, that's where things might go wrong in the same way as,
you know, Twitter turning ourselves into kind of strange scale effects.
I would love Origin of Life research or artificial life research to get to the point where we have those worries.
Because that's why I think we're just so far away from that. We are just, you know, right now I think there are two really important angles. There is the origin of life, people, researchers who
are faithfully working on this and trying to make those molecules, the scam molecules
I talked about. And then there are people on the creationist side who are saying, look,
the fact you can't make these molecules and you can't make a cell means that evolution
isn't true and all this other stuff.
Gotcha. Yeah. And so, and I find that really frustrating because actually the origin of
life research is all working in good faith
Right, and and so what I'm trying to do is give origin of life research a little bit more of a of an open
An open context and one of the things I think is important
I really want to make a new life form in my lifetime. I really want to prove that life is a general phenomena
form in my lifetime. I really want to prove that life is a general phenomena, a bit like gravity in the universe, because I think that's going to be really important for humanity's
global psychological state, meaning going forward.
That's beautifully put. So one, it will help us understand ourselves. So that's useful for science, but too, it gives us a kind of hope, if not,
an awe at all the huge amounts of alien civilizations that are out there. If you can build life and
understand just how easy it is to build life, then that's just as good if not much better than discovering life on another planet.
Yeah.
It's, I mean, it's cheaper.
It's much cheaper and much easier and probably much more conclusive because once you're
able to create life, like you said, it's a search problem that there's probably a lot
of different ways to do it.
Yeah. Once you create the, once you find
the first solution, you probably have all the right methodology for finding all kinds of other
solutions. Yeah, and wouldn't it be great if we could find a solution? I mean, it's probably a
bit late for, I mean, I worry about climate change, but I'm not that worried about climate change.
And I think one day you could think about, could we engineer a new type of life form that could
basically, and I don't want to do this,
so I don't think we should do this necessarily,
but it's a good thought experiment
that would perhaps take CO2 out of the atmosphere
or an intermediate life forms.
It's not quite alive, it's almost like an add-on
that we can, as time dependent add-on,
you could give to say cyanobacteria in the ocean
or to maybe to wheat. So right,
we're just gonna fix a bit more CO2 and we're gonna work how much we need to fix to basically
save the climate and we're gonna use evolutionary principles to basically get there.
What worries me is that biology has had a few billion years to find a solution for CO2 fixation,
hasn't really done.
It's not the solution isn't brilliant for our needs, but biology wasn't thinking about
our needs, biology was thinking about biology's needs.
But I think if we can do, as you say, make life in the lab, then suddenly we don't need
to go to everywhere and conclusively prove it.
I think we make life in the lab, we look at the extent of life in the solar system, how
far did Earth life get?
Probably we were all Martians.
Probably life got going on Mars,
the chemistry on Mars, seeded Earth.
That might have been a legitimate way
to kind of truncate the search space.
But in the outer solar system,
we might have completely different life forms
on the cellos, on Europa, and Tyson.
And that would be a cool thing.
Because-
Okay, wait a minute, wait a minute, wait a minute, wait a minute.
Did you just say that you think in terms of likelihood,
life started on Mars, like I specifically speaking,
life started on Mars and seated at Earth?
It could be possible, because life was,
Mars was habitable for the type of life that we have right now,
type of chemistry before Earth.
So it seems to me that Mars got searching, doing chemistry,
like, and-
So started way before.
Yeah, and so they were had a few more replicators
and some other stuff.
And if those replicators got ejected from Mars
and landed on Earth,
an Earth would be like, I don't need to start again.
Right.
Thanks for that.
And then it just carried on.
So I'm not going, I think we will find evidence of life on Mars, either life we put there by mistake, contamination, or actually
life, the earliest remnants of life. And that we really exciting. It's a really good reason
to go there. But I think it's more unlikely because of the gravitational situation in the
social system. If we find life in the outside system, tighten and all that, that'll be its
own thing. Exactly.
Wow, that'll be so cool.
If we go to Mars and we find life that looks
a hell of a lot similar to Earth life,
and then we go to tighten and all those weird moons
with the ices and the volcanoes and all that kind of stuff.
And then we find there something that looks,
I don't know, way weirder.
Yeah.
Some other, some non-RNA type of situation.
Or in my situation.
Almost life, like in the pre-bordic chemical space.
And I think there are four types of exoplanets
we can go look for, right?
Because when JWST goes up and touch wood,
it goes up and everything's fine,
when we look at a star,
we know statistically most stars have planets around them.
What type of planet are they going to be dead?
Are they going to be just a pre-botic origin of life coming? So
are they going to be technological? So we have intelligence on them. And will they have died?
So from, you know, had life on them.
Does it have four states of life?
And so suddenly, it's a bit like I want to classify planets the way we classify stars.
Yeah.
And I think that in terms of that,
rather than having this old,
we've found, we've found methane,
there's evidence of life,
we've found oxygen, there's evidence of life,
we've found whatever molecule marker
and start to then frame things a little bit more.
As those four states, which by the way,
you're just saying four,
but there could be a, before the dead, there could be other states that we humans can even conceive of.
Just prebiotic, almost alive, you know, got the possibility to come alive. I think,
um, but there could be a post technological, like whatever we think of as technology,
there could be a like pre-conscious
like what we all meld into one super intelligent conscious
or some weird thing that naturally happens.
Over time.
I mean, I think that the,
oh, that's the metaverse.
Yeah, we are.
We join into a virtual metaverse
and start creating, which is kind of interesting idea,
almost arbitrary
number of copies of each other much more quickly to a commess with different ideas.
I can create a thousand copies of Lex, like every possible version of Lex, and then just
see, like, and then I just have them like argue with each other and like until like in the
space of ideas and see who wins out.
How, how could that possibly go wrong?
But anyway, but there's a, especially in this digital space where you could start exploring
with AI's mix, then you could start engineering arbitrary intelligences.
You can start playing in the space of ideas, which might move us into a world
that looks very different than a biological world.
Like our current world, the technology,
is still very much tied to our biology. We may move past that.
Definitely. We definitely will.
Definitely. That could be another phase then.
Sure. Because then you'd have to have a...
But I did say technological. So I think I agree with you. I think so.
You can have, let's get this right. So, dead world, no prospect of alive, pre-barotic
world life emerging, living and technological. And you probably were and the dead one, you
probably won't be out of tell between the dead never been alive and the dead one, maybe
some artifacts, and maybe this five, it's probably not more than five. And I think the
technological one could allow, could have life on it still, but it might just have exceeded. Because, you know, one way that life might survive on Earth is if we can work out how to
deal with the coming, the real climate change that comes when the sun expands.
It might be a way to survive that, you know.
But, yeah, I think that we need to start thinking statistically when it comes to looking
for life in the universe. Let me ask you then sort of statistically how many alien civilizations are out there
in those four phases that you're talking about. When you look up to the stars and you're
slipping on some wine and talking to other people, British accents, about something intelligent intellectual, I'm
sure.
Do you think there's a lot of alien civilizations looking back at us?
I'm wondering the same.
My romantic view of the universe is really taking loans from my logical self.
So what I'm saying is I have no doubt, I have no idea. But having said that, there is no reason to
suppose that life is as hard as we thought it was.
And so if we just take Earth as a marker
and if I think that life is a much more general phenomenon
than just our biology, then I think the universe is full of life.
And the reason for the Fermi paradox is not that
they're not out there, it's just that we can't interact with other life forms because they're so different. And I'm not saying that they're necessarily like hasn't depicted in arrival or other,
you know, I'm just saying that perhaps there are very few universal facts in the universe
and that and maybe that is not it's quite the technology is a quite divergent
and so I think that it's very hard to know how we're going to interact with alien life.
You think there's a lot of kinds of life that's possible. I guess that was the intuition. Yeah. You provided that the way biology itself, but even this particular kind of biology that we
have on earth, is something that is just one sample of nearly infinite number of other possible
sample of nearly infinite number of other possible complex autonomous self-replicating type of things that could be possible. And so we're almost unable to see the alternative versions of us.
Huh. I mean, we still be able to detect them. We still be able to interact with them, we'll still be able to like which,
what's exactly is lost in translation? Why can't we see them, why can't we talk to them?
Because I too have a sense, you put it way more poetically, but it seems both statistically
It seems both statistically and sort of romantically, it feels like the university be teaming with life, like super intelligent life.
And I just, I sit there and the Fermi paradox is very, is felt very distinctly by me when
I look up at the stars because it's like it's
the same way I feel when I'm driving through New Jersey and listening to Bruce
Bringson and feel quite sad. It's like Lucy K talks about pulling off to the side
of the road and just weeping a little bit. I'm almost like wondering like, hey
why aren't you talking to us? You know, it feels lonely. It feels lonely because it
feels like they're out there.
I think that there are a number of answers to that. I think the Fermi paradox is perhaps based on the assumption that if life did emerge in the universe, it would be similar to our life.
And there's only one solution. And I think that what we've got to start to do is go out and look for selection detection,
rather than an evolution detection, rather than life detection.
And I think that once we start to do that, we might start to see really interesting things.
And we haven't been doing this for very long.
And we are living in an expanding universe, and that makes the problem a little bit harder.
Everybody's always leaving. But I'm...
distance wise.
I'm very optimistic that we will... Well, I don't know. There are two movies that came out
in the same within six months of one another.
Ad Astra and Cosmos.
Ad Astra, the very expensive blockbuster, you know, with Brad Pitt in it and saying there is no life
and it's all, you know, we've got a it and saying there is no life and it's all,
you know, we've got a life on earth as more precious and cosmos, which is a UK production,
which basically aliens came and visited Earth one day and they were discovered in the UK.
Right, it was quite, it's a fun film. But I really loved those two films and I,
I know at the same time, those films, at the time those films are coming out, I was working on a paper,
I know at the same time, at the time those films are coming out, I was working on a paper,
a live detection paper, and I thought it was so hard to publish this paper.
And it was almost as depressed, I got so depressed trying to get this science out there, that I felt the depression of the film in Alastair, like life is, there's no life else
we're in the universe. But I'm incredibly optimistic that I think we will find life in the universe
firm evidence of life and it will have to start on earth
making life on earth and surprising us.
We have to surprise ourselves and make non-biological life on earth.
And then people say, well, you made this life on earth.
Therefore, it's your part of the causal chain of that.
And that might be true.
But if I can show how I'm able to do it with a very little cheating or very
little information inputs just creating like a model planet, some description
and watching it watching life emerge, then I think that we will be even to
persuade even the hardest critic that it's possible.
Now with regards to the Fermi paradox,
I think that we might crush that with the JWST. It's basically, if I recall correctly,
the mirror is about 10 times the size of the Hubble, that we're going to be able to do spectroscopy,
look at colors of exoplanets, I think, not brilliantly, but we'll be able to start to classify them,
think, not brilliantly, but we'll be able to start to classify them. And we'll start to get a real feel for what's going on in the universe on these exoplanets, because it's
only in the last few decades, I think, maybe even last decade, that we even came to recognize
that exoplanets even are common. And I think that that gives us a lot of optimism that life is
going to be out there. But I think we have to start framing. We have to start preparing the fact
that biology is only one solution. I can tell you with confidence that biology on Earth does not
exist anywhere else in the universe. We are absolutely unique. Well, okay, I love the confidence, but where does that confidence come from,
you know, chemistry, like, how many options does chemistry really have?
Many, that's the point. And the thing is, this is where the origin of life scam comes
in, is that people don't quite count, they don't count the numbers. So if biology, as you find on earth, is common
everywhere, then there's something really weird going on. But basically written in the
quantum mechanics, there's some kind of, these bonds must form over these bonds, and this catalyst
must form over this catalyst when they're all quite equal. Life is contingent. The origin of life
on earth was contingent upon the chemistry available at the origin of life on Earth.
So that means if we want to find other life-like, other earth-like worlds,
we look for the same kind of rocky world, we might look in the same zone as Earth,
and we might expect reasonably to find biological-like stuff going on.
That would be a reason why I'm a physicist, but it won't be the same. It can't be. It's like saying, I
don't believe in magic. That's why I'm sure. I just don't believe in
magic. I believe in statistics and I can do experiments. And so I
won't get the same, exactly the same sequence of events. I'll get
something different. And so there is TikTok elsewhere in the
universe, but it's not the same as our TikTok, right?
That's what I mean.
Which aspect of it is not the same?
Well, I just think it, you,
the, so what is TikTok?
TikTok is a social media where people upload videos, right?
Of silly videos.
So I guess there might be.
Well, there's humor, there's attention,
there's an ability to process,
there's ability for intelligent organisms
to collaborate on ideas
and find humor and ideas and play with those ideas and make them viral.
Memes, you know, humor seems to be kind of fundamental to the human experience.
And I think that that's a really interesting question we can ask is humor a fundamental
thing in the universe I think maybe it will be, right? In terms of, you think about in a game, theoretic sense, humor, the emergence of humor serves a role in our game engine.
And so, if selection is fundamental in the universe, so is humor.
Well, I actually don't know exactly what role humor serves.
Maybe it's like a chemical perspective.
It's like a catalyst for, I maybe it's like a chemical perspective. It's like a catalyst
for
I guess it's a several purpose one is the catalyst for spreading ideas on the internet that's modern humor
But humor is also a good way to deal
With the difficulty of life. It's a kind of valve release valve for suffering
that kind of valve release valve for suffering. The throughout human history life has been really hard.
And for the people that have known in my life who've looked at some really difficult things,
humor is part of how they deal with that.
Yeah.
It's usually dark humor.
But yeah, it's interesting.
I don't know exactly sort of what's the more mathematically general way to formulate what the hell is humor
humor as it's served, but I still we're kind of joking here, but
It's an a counter intuitive idea to me to think that
life elsewhere in the universe
is very different than life on earth.
And also, like, all of each instantiation of life is likely very different from each other.
Like, maybe there's a few clusters of similar like life,
but it's much more likely that you're saying, to me, it's a kind of novel thought. I'm not sure what to do with it
But you're saying that there's a it's more common to be a weird august in
The full spectrum of life than it is to be in some usual cluster
So every instantiation of a kind of
Chemistry that results in complexity that's autonomous and self-replicating however the hell you define life, that is going to be very different every time. I don't know.
It feels like a selection is a fundamental kind of directed force in the universe.
One selection result in a few pockets of interesting complexities. I mean, yeah, if we ran Earth over, again, over and over and over, you're saying it's
going to come up, but there's not going to be elephants every time.
Yeah, I don't think so.
I think, and I think that there will be similarities.
And I think we know, we don't know enough about how selection is globally works.
But it might be that the emergence of elephants
was wired into the history of earth in some way,
like the gravitational force, how evolution was going,
but you can can bring explosions,
blah, blah, blah, the emergence of mammals.
But I just don't know enough about the contingency,
right, the variability.
All I do know is you count the number of bits of information required to make an element,
sorry, an elephant, and think about the causal chain that provide the lineage of elephants
going all the way back to Luka, there's a huge scope for divergence.
Yeah, but just like you said, with chemistry and selection, the things that result in self-replicating
chemistry and self-replicating organisms, those are extremely unlikely, as you're saying,
but once they're successful, they multiply.
So it might be a tiny subset of all, of all
things that are possible in the universe, chemically speaking, it might be a very tiny subset
is actually successful at creating elephants or an elephant like, or a slash human like
creature.
Well, it's two different questions. It's the first one. If we were to reset earth and
to start again, we're different phases, sorry to keep interrupting. Yeah, no, if we restart Earth and start again,
say we could go back to the beginning and do the experiment
or have a number of the Earths, how similar would biology be?
I would say that there would be, there would be broad similarities.
But the emergence of mammals is not a given.
And this we're going to, you know,
throw an asteroid at each planet at each time
and try and, try and faithfully reproduce what happened.
Then there's the other thing
about when you go to another lot of Earth-like planet elsewhere, maybe there's a different
ratio, particular elements, maybe there's the bombardment at the beginning of the planet
was quicker or longer than Earth. And I just don't have enough information there. What I do know is that the complexity of the story of life
on Earth gives us lots of scope for variation.
And I just don't think it's a reasonable mathematical assumption
to think that life on Earth, it happened again,
would be same as what we have now.
OK.
But you've also extended that to say that we might,
as an explanation for the
Fermi paradox, that means we're not able to interact with them.
Or that's an explanation for why we haven't at scale heard from aliens is...
Well, right now.
They're different than us.
We've only been looking for, say, 78 years.
So I think that we, the reason we have not found aliens yet, is
that we haven't worked out what life is.
No, but the aliens have worked that out, surely. I mean, statistically speaking, they
must be, there must be a large number of aliens. They're way ahead of us on this whole
life question. Unless there's something about this stage of intellectual
evolution that often quickly results in nuclear war
and destroys itself.
Like, there's something in this process that eventually,
I don't know, crystallizes the complexity
and it either dies or stops developing.
But most likely, they already figured it out.
And why aren't they contacting us?
There's some, some grad student somewhere who wants to study a new green planet.
Maybe they have.
I mean, I don't have a coherent answer to your question, other than to say that if there
are other aliens out there and they're
far more advanced, they might be in contact with each other. And they might also, we might be at a
point where what I'm saying quite critically is it takes two to talk, right? So the aliens might
be there, but if we don't have the ability to recognize them and talk to them, then the aliens
aren't going to want to talk to us. And I think
that's an critical point then probably if that's a filter, there needs to be an ability
for one to communicate with the other. And we need to know what my fears before we do
that. So we haven't qualified to even join the club to have a talk.
Well, I think they still want to teach us how to talk, right? But my
worry is that, or I think they would want to teach us how to talk like you do when you
meet it, like, when you even meet, I was going to say, child, but that's a human species.
I mean, like, and you want to try to communicate with them, the whatever devices you can, given what an
ant is like.
I just, I worry mostly about that humans are just too close minded or don't have the
right tools.
No, I'm going to push back on this quite significantly.
I would say because we don't understand what life is.
And because we don't understand how life emerged in the universe, we don't understand the
physics that
gave rise to life yet. And that means our fundamental description, I'm way out of my
pay grade even further out, but I'll say it anyway, because I think it's fun to get paid
in my January.
So as you said earlier, so. So I would say that we, because we don't understand the universe,
yet, we do not understand how the universe spat out life. And we don't understand the universe yet. We do not understand how the universe spat out life.
And we don't know what life is.
And I think that until we understand that,
it is gonna limit our ability to even,
we don't qualify to talk to the aliens.
So I'm gonna say that they might be there,
but I'm not gonna say that I believe
in interdimensional aliens being present in this.
But I think you're just being self-critical,
like we don't qualify.
I think the fact that we don't qualify qualifies us.
We're interesting, we're interesting in our innocence.
No, I'm saying that because we don't understand causal chains and the way that information
is propagated in the universe and we don't understand what replication is yet and we don't
understand how life emerged. I think that we would not recognize aliens,
and if someone doesn't recognize you,
you wouldn't go and talk to it.
You don't go and talk to ants.
You don't go and talk to birds,
or maybe some birds you do, right?
Because you can.
There's just enough cognition.
So I'm saying because we don't have enough cognitive abilities are not yet where they need to be.
We probably aren't communicating with them. So you don't agree with the dating strategy of playing hard to get?
Because us humans, that's just a tractor. We're within a species that's fine, but I think we don't actually have abstraction.
No, I actually, I think you've in this talk, in this conversation, you've helped me crystallize
something that I think has been troubling me for a long time with a thermoparadox.
I'm pretty sure that a reasonable avenue is to say that you would not go and talk to
your cat about calculus, right?
But I was still pet it.
Sure, but I'm not talking about petting and cat.
The analogy is that the aliens are not going to talk to us because we, and I'm using calculus
as an analogy for abstraction, because we lack the layer, the fundamental layer, understanding
what life is and what the universe is in our reality that it's, it would be so counterproductive
interacting with intelligent alien species that it would cause more
angst for the unit for human race. But they don't care. Okay, they've got to be self-interested. So
they'll probably, they more care about is an interesting for them. Maybe they, I mean, surely there's
a way to pat the cat in this, because even if we lack complete understanding,
it must be a very frustrating experience for other kinds of intelligence that communicate
with us, still there must be a way to interact with us.
Well, like, perturb the system in interesting ways to see what these creatures do. We might actually find the answer, I mean again, at my pay graded, in a simulation of Earth.
We'll say, let's say a simulation where we allow an intelligent AI to emerge, right?
And that AI, we then give it the objective is to be curious, interactive, other intelligence
in its universe.
And then we might find the parameters required for that AI to work with, and I think you'll
find, the AI will not talk to other AI's that don't share the ability to abstract the
level of the AI because it's just a cat.
And are you going to travel 20 light years to go and pet a cat? So not because of the inability to do so, but because of like boredom is that it's more
interesting. It will start talking to it will spend most it will spend a majority of
its time talking to other AI systems that can at least someone understand it's much more
fun. It's a bit like do we know that plants are conscious? Well, plants aren't conscious
in the way we typically think,
but we don't talk to them.
They could be, right?
But there's a lot of people on earth who like gardening.
There's always going to be a weirdo thing.
They're just gardening.
Okay.
Well, you're not romantic enough to see gardening
as a way of communication between humans and...
Oh, okay, you've got me there.
But there's always going to be the people who are curious.
Jane Goodach, who lives with the chimps, right? There's always going to be the people who are curious. Jane Goodall, who lives with the chimps, right?
There's always going to be curious intelligence
species that visit the weird earth planet
and try to interact.
I mean, it's a, yeah, I think it's a super cool idea
that you're expressing.
I just kind of have a sense.
Maybe it's the hope that there's always going to be a desire
to interact, even with those that can't possibly understand the depth of what you understand.
So, I'm with you, so I want to be a positive issue that the aliens do exist and we will
interact with them.
What I'm trying to do is to give you a reasonable hypothesis why we haven't yet. And also something to strive for,
to be able to do that.
I mean, there is the other view
that the universe is just too big
and life is just too rare.
But I want to come up with an alternative explanation,
which I think is reasonable,
and not being philosophically and scientifically thought out,
which is this, if you can't actually
communicate with the object, the person, the thing, competently, you don't even know it's there.
Yeah. Then, then there's no point yet. See, I disagree with that, but I'm totally
aligned with your hopeful vision, which is like, we need to understand the origin of life.
There will help us engineer life, will help us engineer intelligent life through perhaps on the computer side of simulation
and explore all the ways that life emerges.
And that will allow us to,
I think the fundamental reason
we don't see overwhelming amounts of life
is I actually believe aliens,
of course, these are all just kind of open mind
I believe is difficult to know for sure about any of this, but I think there's a lot of alien
civilizations which are actively communicating with us.
And we're too dumb.
We don't have the right tools to see it.
That's what I'm saying.
No, but maybe I'm a centurbre to you, but I interpret to you just say they kind of tried
a few times and they're like,
oh God, you know, no, no, what I'm saying is we, so this goes two ways.
Yeah, I agree with you. There could be information out there, but just put in such a way that we just don't understand it yet.
Right. So, sorry, I forgot to make that clear. I mean, it's not just, I don't think we qualify,
as soon as we can decode their signal. Right, So when you say qualific, got to got it.
So you mean we're just not smart enough though, the word qualific, I was to be off.
So we're not smart enough to do.
There's like, yeah, but we need to get smarter there.
And there's a lot of people who believe, let me get your opinion on this about your full sightings.
So sightings of weird phenomena that, you know, what does UFO mean?
It means it's a flying object and it's not identified clearly at the time of sighting.
That's what UFO means.
So it could be physics phenomena, it could be ball lightning, it could be all kinds of
fascinating. I was always fascinating with ball lightning. Like the fact that there
could be physical phenomena in this world that are observable by the human eye, of course
all physical phenomena generally are fascinating that are that really smart people can't explain.
I love that because it's like, wait a minute.
Especially if you can replicate it.
It's like, wait a minute, how does this happen?
That's like the precursors of giant discoveries
in chemistry, biology, and physics and so on.
But it sucks when those events are super rare, right?
Physically like leg ball lightning.
So that's out there.
And then of course that phenomena could have other interpretations that don't have
to do with the physics of chemistry, the biology of Earth.
It could have to do with more extraterrestrial explanations.
That, a large part, thanks to Hollywood movies and all those kinds of things, captivates
the imaginations of millions of people, but just because it's science
fiction that captivates the imagination of people doesn't mean that some of those sightings,
all it takes is one.
One of those sightings is actually a sign that's its extraterrestrial intelligence, that
it's an object that's not of this particular world. Do you think there's
a chance that that's the case? What do you make, especially the pilot sightings? What do you
make of those? So I agree there's a chance, there's always a chance, any good scientist would
have to, or observationist would have to, you know, I want to see if aliens exist, come to earth.
You know, I want to see if aliens exist come come to earth
What I know about the universe is I think it's unlikely right now that there are aliens visiting us
but but not impossible I think the
releases the dramatization that's been happening politically saying we're gonna release all this information is you know classified information
I was kind of disappointed because it was just very poor material. Right now, the ability to capture high resolution video, everybody is carrying
around with them an incredible video device now. We haven't got more compelling data. And so that we've just seeing
grainy pictures, a lot of hearsay, instrument kind of malfunctions and whatnot. And so
I think on balance, I think it's extremely unlikely, but I think something really interesting
is happening. And it also during the pandemic, right, we've
all been locked down. We all want to have, we want to, our imaginations are, you know,
running riot. And I think that the, I don't think that the information out there has convinced
to be there are anything interesting on the UFO side. But what has made me very interesting
about is how humanity is opening up its mind to ponder aliens and the mystery of our universe.
And so I don't want to dissuade people from having those thoughts and say, you're stupid and
look at that, it's clearly incorrect. That's not right, that's not fair. What I would say is that
I lack sufficient data replicated observations to make me go, oh, I'm going to take this seriously,
replicated observations to make me go, oh, I'm going to take this seriously,
but I'm really interested by the fact that there is this
great deal of interest.
And I think that it drives me to maybe want to make
an artificial life for me even more,
and to help NASA and the Air Force
and whoever go and look for things even more,
because I think humanity wants to know what's out there. There's this yearning isn't there. Yeah, but but I see I almost
Depending on the day I sometimes agree with you, but with the thing you just said, but
One of the disappointing things to me about the sightings I
Still hold the belief that a non-zero number
of them is an indication of something very interesting. So I don't side with the people
who say everything you can be explained with like a sensor artifacts kind of thing.
Yeah, I agree with you. I didn't say that either. I would say I just don't have enough data.
Right.
But the thing I want to push back on is the statement
that everybody has a high definition camera.
One of the disappointing things to me about the report
that the government released, but in general,
just having worked with government,
having worked with people all over,
is how incompetent we are. Like if you look at the
response to the pandemic, how incompetent we are in the face of
great challenges without great leadership, how incompetent we are
in the face of the great mysteries before us without great
leadership. And I just think it's actually the fact that there's a
lot of high definition cameras is not enough to capture the full richness of weird of the mysterious phenomenon out
there of which extraterrestrial intelligence visiting Earth could be one. I don't think
we have, I don't think everybody having a smartphone in their pocket is enough. I think
that allows for TikTok videos. I don't think it allows
for the capture of even interesting relatively rare human events. That's not that common. It's rare
to have been the right moment in the right time to be able to capture the thing. I agree, I agree. Let
me, let me rephrase what I think on this. I haven't seen enough information. I haven't really actively sought it out. I must admit, but I'm with you in that I love the idea of
anomaly detection in chemistry in particular. I want to make anomalies, sorry, or not necessarily
make anomalies. I want to understand an anomaly. Let me give you two from chemistry. It's a really quite interesting.
Flegistan, going way back, where people said, this is think called Flegistan. And for ages,
the alchemist got really this kind of, that this, that fire is a thing. And that's one.
And then we determined that for Flegistan wasn't what we thought it is. There's got physics,
the ether. The ethers are a hard one because I think actually the ETH might exist and I'll tell you what I think the
ETH for is later. And it can explain ether. So as the vacuums, the light traveling through the
ETH for in the vacuum, there is something that we call the ether that basically mediates the movement
of light. And then the other one is cold fusion,
which is more, so a few years ago,
that people observed it when they did some electrochemistry
when they were splitting water into hydrogen and oxygen
that you got more energy out than you put in.
And people got excited and they thought
that this was a nuclear reaction.
And in the end, it was kind of discredited because you didn't detect neutrons and all
stuff.
But I'm pretty sure I'm a chemist.
I'm going telling you this on your podcast, but why not?
I'm pretty sure there's interesting electrochemical phenomena that's not completely bottomed
out yet, that there is something there.
However, we lack the technology and the experimental design. So all I'm saying in your response to about aliens is, we lack the technology and the experimental design.
So all I'm saying in your response to the aliens is,
we lack the experimental design to really capture these anomalies.
And we are in circling the planet with many more detection systems.
We've got satellites everywhere.
So there is, I do hope that we are going to discover more anomalies.
And remember, the solar system isn't just static in space.
It's moving through the universe.
So there's just more and more chance.
I'm not what we've avi-lobe that is generating all sorts
of kind of a cult, I would say, with this.
But I'm not against him.
I think there is a finite chance if there are aliens
in the universe that we're going to happen upon them,
because we're moving through the universe.
What's the nature of the following that Avilob has?
Is doubling down more and more and more and say there are aliens, interdimensional aliens,
and everything else, right?
He's gone from space junk accelerating out of two interdimensional stuff in a very short
space of time.
I see.
He's obviously bored.
Or he wants to tap into the psyche and understand, and he's
playfully trying to interact with society in his peers to say, stop saying it's not possible,
and which I agree with, we shouldn't do that, but we should frame it statistically in the same way
we should frame everything as good scientists statistically. Yeah. Good scientists. Recently, the idea of good scientists is, I take quite skeptically.
I've been listening to a lot of scientists tell me about what is good science.
That makes me sad because you've been in, if you're you're well I would consider a lot of really good scientists know that's true and but that that's exactly right and most of the people
I talk to are incredible human beings, but there's a humility that's required science is not
Science cannot be dogmatism sure I agree. I mean authority
like
a PhD does not give you authority a lifelong pursuit of a a PhD does not give you authority.
A lifelong pursuit of a particular task
does not give you authority.
You're just as lost and clues to everybody else,
but you're more curious and more stubborn.
So that's a nice quality to have.
But overall, just using the word science
and statistics can often, as you know, kind of become a catalyst
for dismissing new ideas out of the box ideas, wild ideas, all that kind of stuff.
Well, yes and no.
I think that so I'm I like to
Some people find me extremely annoying in science because I'm basically I
Quite rude and disruptive not in a rude, you know It's so up to people and say they're ugly or stupid or anything like that. I just say
You know, you're wrong. Well, why do you this? And and something I I gift I got given by
society when I was very young because I was in a in the learning difficulties class at school
as I was told I was stupid. And so I know I know I'm stupid, but I always wanted to be smart,
right? I always I remember going to school gang. Maybe today they're going to tell me I'm not
as stupid as it was yesterday. And it was always always disappointed always and so when I went into academia and everyone said you're wrong. I was like
Join the queue
Because it allowed me to walk through the you know the wall
So I think that people like to always imagine science is a bit like living in a Japanese house and people walls
Everyone sits in their people in their room
And I annoy people because I walk straight through the wall not because not because why should I be a chemist and not a mathematician?
Why should I be a mathematician, not computer scientist? Because if the problem requires us to walk through those walls,
but I like walking through the walls.
But as long as I have to put up, you know, I have to do good side. I have to win the people in those rooms across by good science,
by taking their criticisms and addressing them head on. And I think we must do that. And I think
that I try and do that in my own way. And I kind of love walking through the walls.
And it gives me, it's difficult for me personally, it's quite painful, but it always leads to a deeper understanding
of the people I'm with, and particularly,
you know, the arguments I have with all sorts of interesting minds,
because I want to solve the problem,
or I want to understand more about why it exists.
You know, that's it, really.
And I think we have to not dismiss science on that basis.
I think we can work with science.
No, science is beautiful, but humans with egos
and all those kinds of things can sometimes misuse
good things like social justice.
Like all ideas were all aspire to misuse
these beautiful ideas to manipulate people to all those kinds of things.
And that's there's assholes in every space and walk of life, including science. And those are
no good. But yes, you're right. The scientific method has proven to be quite useful. That said, for difficult questions, for difficult
rare explanations for rare phenomena, you have to walk cautiously. Because the scientific
method, when you totally don't understand something, and it's rare, and you can't replicate
it, doesn't quite apply.
Yeah, yeah, yeah, I agree with you. The challenge is to not dismiss you normally because you
can't replicate it. I mean, we can talk about this. This is something I realized when
we were developing assembly theory. People think that the track they're on is so dogmatic
where there is this thing that they see, but
they don't see.
And it takes a bit of time and you just have to keep reframing it.
And my approach is to say, well, why can't this be right?
Why must we accept that RNA is the only way into life?
I mean, who said, does RNA have a special class of information that's encoded in the universe?
No, of course it doesn't, right?
You know, RNA is not a special molecule in the space of all the other molecules.
But it's all elegant and simple and it works so well for the evolutionary process that we
kind of use that as intuition to explain that that must be the only way to have life.
Sure.
But you mentioned assembly theory.
Well, first let me pause, bathroom break. break needed. Yeah, let's take two minutes
Which took a quick break and offline you mentioned to me
That you have a lab in your home and
Then I said that you're basically Rick from Rick and Morty, which is something I've been thinking this whole conversation
And then you say that there's a glowing pickle
that you used something involving coal plasma, I believe. I don't know, but can you explain the glowing pickle situation?
And is there many arbitrarily many versions of you in alternate dimensions?
So I think you're aware of of I tried to make an electrochemical
memory in at home
using a and the only work using a pickle the only work it get any
Traction with it was actually by plugging it into a very high voltage
alternate in current and then putting in a couple of electrodes
But my kids weren't impressed. They're not in-pressive anything.
I do it any experiments.
I do it at home.
I think it's quite funny.
But you connected your pickle to some of the electrode,
I mean, you do.
240 volts, yeah, AC.
Yeah.
And then had a couple of electrodes on it.
So what happens is a pickle,
this is a classic thing you do.
I mean, I shouldn't prank you.
You put a pickle into their mains
and just run away and leave it.
And what happens is it starts to decompose, it heats up and then explodes because the water turns to steam
and it just violently explodes. But I wondered if I could cause the iron, sodium, potassium
ions and the pickle to migrate. It'd been in a jar, right? So it'd be in a brine. That
was not my best experiment. So I've deemed far better experiments in my lab at home.
At that time was a failed experiment, but you never know, it could...
Every experiment is a successful experiment if you stick with it long enough.
I mean, I got kicked out of my own lab by my research team many years ago.
I'm for good reason. I mean, my team is brilliant and I used to go and just break things.
So what I do do at home is I have a kind of electronics workshop and I prototype experiments there
and then I try and suggest to my team sometimes, maybe we can try this thing.
And they would just say, oh, well, that's not going to work because of this.
And I'm saying, aha, but actually I've tried and here's some code and here's some hard
work and we have a go.
So I'm doing that less and less now
as I get even more busy, but that's quite fun
because they feel that we're in the experiment together.
You do, in fact, brilliantly,
just like Rick from Rickomorty,
connects a chemistry with computation.
chemistry with computation. So, sort of, and when we say chemistry, we don't mean the simulation of chemistry, of
modeling of chemistry.
We mean chemistry in the physical space, as well as in the digital space, which is fascinating.
We'll talk about that.
But first, you mentioned assembly theory.
So we'll stick on theory in these big ideas.
I'll say revolutionary ideas.
That's an intersection between mathematics and philosophy.
What is assembly theory?
And generally speaking, how would we recognize life if we saw it?
So assembly theory is a theory. it goes back a few years now,
my struggle for maybe almost 10 years when I was going to origin of life conferences and
artificial life conferences where I thought that everybody was dancing around the problem of what
life is and what it does. But I'll tell you about what assembly theory is because I think it's
easier. So assembly theory literally says,
if you take an object, any given object,
and you are able to break the object into parts,
very gently, so just maybe it's let's say,
take a piece of very intricate Chinese porcelain,
and you tap it, just one the hammer,
or the nail at some point,
and it will fragment into many parts.
And if that object is able to fragment into
many and you count those parts, the different parts, so they're unsymmetrical. Assembly
theory says the larger the number of parts, unsymmetrical parts that object has, the more
likely it is that object has been created by an evolutionary or information process, especially if that object
is not one off, you've got an abundance of them. And that's really important. The abundance,
and I, and I, so because if you, what I'm literally saying about the abundance, if you have a one
off object and you break it into parts, and it has lots of, lots of parts, you'd say, well, that's,
that could be incredibly intricate and complex, but it could be just random.
And I was troubled with this for years because I saw in reality the assembly theory works.
But when I talked to very good computational, complexity computation lists, algorithmic complexity people,
they said, you haven't really done this properly, you haven't thought about it. It's like, this is the random problem. And so I kept working this up because I invented an
assembly theory in chemistry, first of all, with molecules. And so the thought experiment was
how complex does a molecule need to be when I find it that it couldn't possibly have risen by
chance probabilistically. And if I found this molecule
able to detect it enough quantities and say an object like a machine like a mass spectrometer,
so typically in a mass spectrometer you weigh the molecules in the electric field,
you probably have to have on the order of 10,000 identical molecules to get a signal.
So 10,000 identical molecules are complex. Was it a chance of them occurring by chance? Well, we can do the math. Let's take a molecule
like striccnein or yeah, so striccnein is a good molecule actually to take. Or Viagra is a good
molecule. I made jokes about Viagra because it's complex molecule. And one of my friends said,
yeah, if we find Viagra on Mars in detectable quantities, we know something is up.
Vagra on Mars in detectable quantities, we know something is up.
Yeah, but anyway, it's a complex molecule.
So what you do is you take this molecule in the mass spectrometer and you hit it with some electrons or in electric field and it breaks apart.
And if the larger than the larger than the number of different parts, you know
when it starts to get to a threshold, my idea was that that molecule could not be created by chance probabilistically So that was where assembly thought theory was born in an experiment in a mass spec experiment
And I was thinking about this because NASA sending a mass spectrometer to Mars to Titan is gonna send them to Europa
There's gonna be a nuclear powered mass spectrometer going to Titan
I mean, this is a coolest experiment ever
They're not only sending a drone that's going to fly around Titan. It's going to be powered
by a nuclear slug, a nuclear battery, and it's going to have a mass spectrometry on it.
Is this already launched? No, it's Dragonfly and it's going to be launched in a few years.
I think it got pushed a year because of the pandemic. So I think you feel free of fire. Dracking fly, nuclear dragon fly is going to fly the Titan and collect data about the composition
of the various chemicals on Titan.
Yeah, I'm trying to convince NASA. I don't know if I'll be at a convince the Dragon fly
team that they should apply this approach,
but they will get data and depending on how good their mass spectrometer is.
But I had this thought experiment anyway, and I did this thought experiment.
And for me, it seemed to work. I turn the thought experiment into an algorithm
in assembly theory, and I basically assembly theory. If I take, let's just make it generic,
and let's just take the word apricot apra.
So can I, if you find the word, so if you have a book with lots of words in it and you
find apricot apra one off and there's a rap book that's been written by in a random
way, you know, set of monkeys in a room and you're anti-project.
And you're anti-prayers and you find one off apricot apra, no big deal, but if you find
lots of reoccurrences of apricot apra, well that means something weird is going on. But let's think about the assembly number of apricadabra, no big deal. But if you find lots of reoccurrences of abracadabra, well, that means something weird is going on.
But let's think about the assembly number of abracadabra.
So abracadabra has a number of letters in it.
You can break it down, so you just cut the letters up.
But when you actually reassemble abracadabra,
the minimum number of weights of organizing those letters,
so you have an A, a B, you know, and keep going up.
There's just that you can,
when you cut apricotabra up into parts,
you can put it together and get in seven steps.
So what does that mean?
That means if you basically don't read,
you're allowed to reuse things you make in a chain
at the beginning.
That's the memory of the universe,
the process that makes apricotabra.
And because that calls all chain, you can then get to apricodabra. And because that causal chain, you can then get to
apricodabra quicker than the number of letters
for having to specify only in seven.
So if you take that to a molecule and you cut the molecule up
into parts, and you can, on the causal chain,
and you basically start with the atoms and then bonds,
and then you randomly add on those parts to make the A,
make the B, and
keep going all the way up, I found that literally a assembly theory allows me to say how compressed
a molecule is, so when there's some information in there. And I realized the assembly theory
isn't just confined to molecular space, it can apply to anything, but let me finish
the molecular argument. So what I did is I had this theory, I was one of my students we wrote in algorithm, we
basically took 20 million molecules from a database and we just calculated their assembly
number and that's the index.
Like basically, if I take a molecule and I cut it up into bonds, what is the minimum
number of steps I need to take to reform that molecule from atoms?
So reusability of previously formed things is somehow fundamental part of our bodies.
Exactly.
It's like memory in the universe, right?
I'm making lots of leaps here, like it's kind of weird.
I'm saying, right, there's a processor can form the A and the B and the C, let's say.
And then that, and because we've formed A and B before, we can use A and B
again with no extra cost, except one unit. So that's the kind of what the chain of events.
And that's how you think about memory here when you say the universe, when you talk about the
universe or life is the universe creating memory. Exactly. So we went through chemical space and we looked at the assembly numbers, we were able to
classify it. So okay, let's test it, let's go. So we're able to take a whole bunch of molecules
and assign an assembly index to them, okay? And it's just a function of the number of bonds in
the molecule, how much symmetry? So literally assembly theory is a measure of how little symmetry a molecule
has. So the more asymmetry, the more information, the more weird it is, like a Jackson Pollock
of some description. So I then went and did a load of experiments. And I basically took
those molecules, I cut them up in the mass spec and measured the number of peaks without
any knowledge of the molecule. And we found the assembly number, then there was almost a not quite a one-to-one correlation, but almost,
because not all bonds are equal to have different energies. I then did this using two other
spectroscopic techniques, NMR, nucleomagnetic resonance, which uses radio frequency to
basically jangle the molecules and get a signature out. And I also used infrared. And infrared and NMR almost
gave us a one-to-one correlation. So what am I saying? Saying by taking a molecule and
doing either infrared or NMR or mass spec, I can work out how many parts there are in
that molecule and then put it on a scale. And what we did in the next part of the work is we took molecules randomly from the environment,
from outer space, from all round Earth, from the sea, from Antarctica, and from fossils and so on,
and even NASA, because they didn't believe us, blinded some samples, and that we found that all
these samples that came from biology
produced molecules that had a very high assembly number above a threshold of about 15.
So basically, all the stuff that came from that ebiotic origin was low.
There was no complexity there. So we suddenly realized that on Earth at least there is a cut off that
natural phenomena cannot produce molecules
that need more than 15 steps to make them. So I realize that this is a way to make a scale
of life, a scale of technology as well. And literally you could just go sniffing for molecules
or earth on Titan on Mars. And when you find a molecule, and the mass spectrometer that gives you more than 15 parts,
you'll know pretty much for sure that it had to be produced
by evolution, and this allowed me to come up with a general definition
of life based on a assembly theory, to say that if I find an object
that has a large number of parts, say an iPhone,
or Boeing 747, or any complex complex object and I can find it in
abundance and cut it up. I can tell you whether that has been produced by an informational
process or not and that's what Assembly Theory kind of does. But it goes a bit further.
I then realized that this isn't just about life, it's about causation. So actually it
tells you about whether it's a causal structure. So now I can look at objects in the universe, say, again, there's cup
and say, right, I'm going to look at how many independent parts it has. So that's the
assembly number. I'll then look at the abundance of how many cups are two on this table. Maybe
there's a few more, you got stashed away. So assembly is a function of the complexity
of the object times the number of copy numbers of that object or a function of the complexity of the object
times the number of copy numbers of that object
or a function of the copy number normalized.
So I realize there's a new quantity in the universe.
You have energy, entropy, and assembly.
So assembly the way we should think about that
is how much reusability there is.
Because reusability is like the,
like, can you play devil's advocate to this?
So like, could this just be a nice tertiary signal
for living organisms?
Like some kind of distant signal that's,
yeah, this is a nice property,
but it's not capturing
something fundamental. Or do you think reusability is something fundamental to the life and
complex organisms?
I think reusability is fundamental in the universe, not just for life and complex organisms
about causation. So I think assembly tells you, if you find objects, because you can do
this trajectory as well, You think about it that
in the unit, the fact there are objects in the universe on earth is weird. You think about it
which should just have a combinator explosion of stuff. The fact that not everything exists
is really weird. Now there. And then there, as I'm looking at two mugs and two water bottles,
and the things that exist are similar and multiply in copies.
Yeah, so I would say that assembly allows you to do something that's statistical mechanics.
And people looking at entropy have got stuck for a while. So I'm making
it pretty bold. I mean, I'm writing a paper with Sarah Walker on this at the moment. And
we're realizing we don't want to get ahead of ourselves because I think that there's lots
of ways where this is, you know, it's a really interesting idea. It works for molecules.
And it appears to work for any objects produced by causation. Could you take a motor car, you can look at the assembly of the motor car, look at a book,
look at the assembly of the book. Assembly theory tells you there's a way of compressing and reusing.
And so when people I talk to information theorists, they say, oh, this is just logical death.
I say it is, like logical death, but it's experimentally measurable.
They say, oh, it's a bit like comagolar of complexity. I said, but it's computable.
And now, OK, it's not infinitely computable.
It gets NP hard very quickly.
It's very hard problem when you get,
but it's not computable enough.
You could tractable enough to be out
to tell the difference between the molecules
that's been formed by the random background and by causation.
And I think that that's really interesting because until now there's no way of
measuring complexity objectively. Complexity has required algorithmic comparisons and programs
and human beings between label things. Assembly is label free. Well, not entirely. We can talk about what that means in a minute. Okay. My brain has been broken a couple of times here.
I'm sorry I explained it really badly.
No, it was very well explained. It was just fascinating. And it's, it's, it's, my brain
is broken into pieces and I'm trying to assemble it. So, NP hard. So when you have a molecule, you're trying to figure out, okay, if we were to reuse parts
of the molecule, which parts can we reuse to, as an optimization problem, Np hard, to
figure out the minimum amount of reused components that will create this molecule.
It becomes difficult when you start to look at a huge, huge molecules, arbitrarily large.
I'm also mapping this. Can I think about this in complexity generally,
like looking at a cellular automata system and saying,
can this be used as a measure of complexity for like an arbitrarily complicated system?
Yeah, I think it can.
It can.
And I think that the question is in what's the benefit?
Because there's plenty of, I mean, in computer science
and mathematics and in physics, people
have been really seriously studying complexity
for a long time.
And I think there's some really interesting problems
of where we cause grade, and we lose information.
And all assembly theory does really.
Assembly theory just explains weak emergence.
And so what assembly theory says, look,
going from the atoms, atoms interact,
those first replicators that build one another.
Assembly at the minimal level just tells you evidence
that there's been replication and selection.
And I think the more selected something is, the higher the assembly.
And so we were able to start to know how to look for selection in the universe.
If you go to the moon, there's nothing a very high assembly on the moon.
It's up to human artifacts we've left there.
So again, let's go back to the sandbox.
In assembly theory says,
if all the sand grains could stick together, that's the infinite combinatorial explosion
in the universe. That should be the default. We don't have that. Now let's assemble sand
grains together and do them in every possible way. So we have a series of minimal operations
that can move the sand together. But all that doesn't exist either. Now, because we have a series of minimal operations that can move the sand together. But all that doesn't exist either.
Now because we have specific memory, we say, what, we're going to put three sand grains
in line or four, make a cross or a triangle or something unsymmetrical.
And once we've made the triangle and the unsymmetrical thing, we remember that, we can
use it again because on that causal chain.
So what Assembly Theory allows you to do is go to the actual object that you find in
space. And actually, the way you get do is go to the actual object that you find in space,
and actually the way you get there is by disassembling.
It's this Assembly Theory works by disassembling objects you have and understanding the steps
to create them.
And it works for molecules beautifully because you just break bonds.
But like you said, Assembly Theory is very difficult.
It's a difficult problem to figure out how to break them apart.
For molecules, it's easy.
If you just keep low enough in molecular weight space, it's good enough.
So it's a complete theory.
When we start to think about objects, we can start to assign,
we can start to think about things at different levels, different atoms.
What do you assign as your atom?
So in a molecule, the atom is really confusing, because the word atom,
I mean smallest breakable part. So in a molecule, the atom is the confusing because the word atom I mean smallest breakable part
So in a molecule the atom is the bond because you break bonds not atoms, right?
Right, right? So in a car the atom might be I don't know a small amount of iron or the smallest you know reusable part a rivet
Piece of plastic or something. So you got to be really careful in a macro process of the atoms might be transistors. And so the amount of assembly that's something as is
a function, you have to look at the atom level. What are you, where are your parts? What
are you counting? That's one of the things you get to choose. What is a, what scale is
the animal? What is the minimal? Exactly. I mean, there's a huge amounts of trade-offs in when you approach a system and try to analyze,
like if you approach Earth, you're an alien civilization, try to study Earth, what is
the atom for trying to measure the complexity of life?
Is it our humans, the atoms?
I would say to start with, you just use molecules.
I can say for sure, if there are molecules of sufficient complexity
on Earth, then I know that life has made them. And then go further and show technology. There are
molecules that exist on Earth that are not possible even by biology. You need a technology and
you need micro-processes to get there. So that's really cool. And there's a correlation between
that, between the coolness of that and assembly number, whatever the measure.
What would you call the measure?
Assembly index.
So there are three fundamental labels.
So there's the quantity of assembly.
And the assembly, so if you have a box, let's just have a box of molecules.
So I'm going to have my box.
We count the number of identical molecules and then we chop each molecule up in an individual molecule class
and calculate assembly number. So basically you then have a function that sums over all
the molecules for each assembly and then you can divide through. So you make it divide
through by the number of molecules. So that's the assembly and Earth for the box. So that will tell you the amount of assembly in the box.
So basically, the assembly equation will come up with is like,
basically, the sum, um, of e to the power of the assembly index for
molecule, i times the number of copies of the molecule, i, and then
you normalize.
So you sum them all up and then normalize.
So some boxes are going to be more assembled than others.
Yeah, that's what they tell me.
So if you were to look at me as a box, the same a box,
am I a sum of my parts?
In terms of like, how do you know what's my assembly index?
So I'd be gentle.
So let's just, we'll talk about the molecules in you.
So let's just take a pile of sand, the same way as you.
And I would take you and just cut up all the molecules.
I mean, and look at the number of copies and assembly number.
So in sand, let's say there's probably going to be nothing more in the assembly number
of two or three, but there might be trillions and trillions of sand grains.
In your body, the assembly number is going to be higher, but there might not be as
quite as many copies because the molecular weight is higher.
So why do you do want to average it out?
You can average it out.
I'm not defined by the most impressive marks.
No, no, you're an average in your wallet.
We're just working this out, but what's really cool is that you're going to have a really
high assembly.
The sand will have a very low assembly.
Your causal power is much higher. You get to make decisions. You're alive. You're aspiring.
Assembly says something about causal power in the universe. And that's not supposed to exist.
Because physicists don't accept that causation exists at the bottom.
So I understand at the chemical level why the assembly is caused
causation the why is it causation because it's capturing the memory
It's a capturing memory, but there's not an action to it. So I'm trying to see
How these two life what is what life does? So I think it's we don't know
So here's a good question. What is life versus what does life do?
Yeah, so that's this is the definition of life, the only definition we need. Right. The assembly and the.
It's basically that life is able to create objects in abundance that are so complex.
The semi-number is so high, they can't possibly form in a environment where
they just run them interactions. So suddenly, you can put life on a scale. And then life doesn't
exist actually, in that case, it's just how evolved you are. And the U is an object because you have incredible causal power. You can go and launch rockets or build cars or create drugs.
You can do so many things. You can build more artifacts
that show that you have had causal power.
That causal power was there's a lineage.
I think that over time,
I mean, realizing that the physics as a discipline has a number of problems associated with it.
Me as a chemist is kind of interesting, that assembly theory. And I'm really, you know,
I want to maintain some credibility in the physicist's size. but I have to push them because their physics
is a really good discipline.
It's reduced the number, physics is about
reducing the belief system,
but they're down to some things in their belief system,
which is kind of, really makes me kind of grumpy.
Number one is requiring order at the beginning
in university magically, we don't need that.
The second is the second law,
well, we don't actually need that. And I-
This is blasphemous. In a minute, I'll recover my career in a second. Although, I think the only
good thing about being the reader's chair means I think there has to be an act of Parliament to fire me.
Yeah. But you can always go to least Twitter and protest.
But you can always go to least Twitter and protest. And I think the third thing is that, so we've got, you know, we've got the order at the
beginning.
Second law.
Yeah, the second law.
And the fact that causation is emergent, right?
And the time is emergent.
All the care I'll just turned off this program.
I think he believes that it's emergent.
So causation is not a...
That's clearly incorrect.
Because we wouldn't exist otherwise.
So, physicists have kind of got confused about time.
Time is a real thing.
Well, I mean, so, look, I'm very happy with the current description of the universe
as physics give me, because I do a lot of stuff.
Right, I can go to the moon of Newtonian physics, I think, and I can understand the orbit of Mercury with relativity. And
so we and I can build transistors with quantum mechanics right and I can do all this stuff.
Yeah. So I'm not saying the physics is wrong. I'm just saying, if we say that time is
fundamental, I time is non-negotiable, there's a global clock. I don't neither. I don't
need to require that
there's order been magically made in the past because that asymmetry is built
into the way the universe is. So if Tom's fundamental, I mean, you've been
referring to this kind of an interesting formulation of that as memory. Yeah.
So, Tom's hard to like put a finger on
like what the hell are we talking about?
Well, it's just a direction,
but memory is a construction,
especially when you have like,
think about these local pockets of complexity,
these non-zero assembly index entities
that's being constructed and they remember.
Never forget molecules. But remember, the thing is, I invented assembly theory.
I'll tell you I invented it. When I was a kid, I mean, the thing is, I keep making fun of
myself from a search group. I've only ever had one idea. I keep exploring that idea over the
40 years or so since I had the idea. I used to think, well, aren't you the idea that the
universe had? So it's very kind of hierarchical. I used to go, well, I aren't you the idea that the universe had.
So it's very kind of hierarchical.
Anyway, go ahead, I'm sorry.
That's, that's very, oh, that's very poetic.
Yeah.
So I think I came up with a assembly theory
with a following idea when I was a kid,
I was obsessed about survival kits.
What is the minimum stuff I would need
to basically replicate my reality?
And I love computers,
and I love technology or what technology was going to become. So I imagined that I would
have basically this really big truck full of stuff. And I thought, well, can I
delete some of that stuff out? Can I have a blueprint? And then and then the
end, I kept making this making smaller and got to maybe half a truck, then to a
suitcase. And then went, okay, more screw it. I want to I want to carry my
entire technology in my pocket.
How do I do it?
And I'm not like I'd have a George Lawrence interestee
of Jolby and, you know, I play.
I came up with a matchbox survival kit.
In that matchbox survival kit,
I would have the minimum stuff
that would allow me to interact the environment
to build my shelter, to build a fishing rod,
to build a water purification system.
And it's kind of like, so what did I use in my box to assemble in the environment,
to assemble, to assemble, to assemble?
And I realized I could make a causal chain in my survival kit.
So I guess that's probably why I've been obsessed with assembly theory for so long.
And I was just pre-configured to find it somewhere. And when I saw it in molecules,
I realized that the causal structure that we say emerges and the physics kind of gets really stuck
because they're saying that time you can go backwards in time. I mean, how do we let physicists get
away with the notion that we can go back in time and meet ourselves. I mean,
that's clearly a very hard thing to let out. The physicists would not let other sciences
get away with that kind of heresy, right? So why physicists will get away with it?
Let's first of all, to push back to play Devils Advocate, you are clearly married to the idea of memory.
You see in this, again, from Rick and Morty Way, you see, you have these deep dreams of
the universe that is writing the story through its memories, through its chemical compounds
that are just building at the top of each other and and they find useful components that can reuse.
And then the reused components create systems that themselves are then reused.
And all in this way construct things.
But when you think of that as memory, it seems like quite sad that you can walk that back.
But at the same time, it feels like that memory, you can walk in both directions and that memory in terms of time.
You could walk in both directions, but I don't think that makes any sense, because the
problem that I have with time being reversible is that, I mean, I'm just a, you know, I'm
a darn experimental chemist, right?
So I love burning stuff, burning stuff and building stuff.
But when I think of reversible phenomena, I imagine in my head, I have to actually
manufacture some time.
I have to borrow time from the universe to do that.
I can't, when anyone says, let's imagine that we can go back in time or reverse ability,
you can't do that, you can't step out of time.
Time is non-negotiable.
It's happening.
Now, but see, you're assuming that time is fundamental,
which most of us do when we go day to day,
but it takes a leap of wild imagination
to think that time is emergent.
No, time is not emergent.
Yeah, I mean, this is an argument we can have,
but I believe I can come up with an experiment.
An experiment that proves that time can
not possibly be emerging.
An experiment that shows how assembly theory
kind of is the way that the universe produces selection
and that selection gives rise to life.
And also to say, well, hang on,
we could allow ourselves to have a theory
that requires us to have
these statements to be possible, like we need to have order in the past, or we can have
used the past hypothesis, which is order in the past, but it's well.
Okay.
And we have to have an arrow of time, we have to require the entropy increases.
And we have to say, and then we can say, look, the universe is completely closed,
and there's no novelty.
All that novelty is predetermined.
What I'm saying is very, very important, that time is fundamental,
which means, if you think about it, the universe becomes more and more novel each step.
It generates more states, and next step than it was before.
So that means bigger search. So what I'm saying is that the universe wasn't capable of consciousness
at day one. Actually, because you don't have enough states, but today the universe is complex.
So it's like how? All right, all right, hold on a second. Now we've pissed off the panseq,
it's two. Okay. No, there's brilliant. Sorry. I'm part of me is just you know joking
I'm in front of this thing
But because you're saying a lot of brilliant stuff and I'm trying to slow it down before my brain explodes
So because I want to break break apart some of the fascinating things you're saying so novelty
novelty is increasing in the universe because the number of states is increasing.
What do you mean by states?
So I think the physicist almost got everything right.
I can't fault them at all.
I just think there's a little bit of dog.
I'm just trying to play devil's advocate.
I'm very happy to be entirely wrong on this, right?
I'm not right on many things at all.
But if I can make less assumptions about the universe with this, then potentially that's
a more powerful way of looking at things.
If you think of time as fundamental, you can make less assumptions overall.
Exactly.
At the time, it's fundamental.
I don't need to add on a magical second law because the second law comes out of the
fact the universe is actually there's more states available.
I mean, we might even be able to do weird things like dark energy in the universe.
Might actually just be time, right? there's more states available. I mean, we might even be out of do weird things like dark energy in the universe might actually
just be time. Right. Yeah. But then you have to still have to
explain why times fundamental because I can give you one
explanation that's simpler time and say God. You know, like just
because it's simple doesn't mean it's but okay, you still have
to explain God and you still have to explain time. Like, why is
it fundamental? So let's just say existence is default, which means time is the default. So how did you
go from the existence? Well, we exist, right? So let's just, let's just be very, we're
yet to talk about what exists. All right, let's go all the way back. Yeah, yeah, okay.
I think it's very poetic and beautiful what you're weaving into this. I don't think this
conversation is even about the assembly, which is fascinating and we'll keep mentioning it as something index
and this idea that I don't think is necessarily connected to time.
Oh, I think it is deeply connected. I can't explain it. You don't think everything you've
said about assembly theory and assembly index can still be
correct even if time is emergent. So yeah right now a 70 theory appears to work. I
appear to be able to measure objects of high assembly and a mass spectromatic
and look at their abundance and you know all that's fine right. It's a nice if
nothing else it's a nice way of looking at how molecules can compress things.
Now am I saying that a time has to be fundamental,
not emergent for assembly theory to work?
No, I think I'm saying that the universe,
it appears that the universe has many different ways
of using time.
You could have three different types of time.
You could just have time that's,
the way I would think a bit,
if you want to hold on to emergent time,
I think that's fine, let's do that for a second.
Hold on to emergent time, and the universe is just doing its thing.
Then assembly time only exists when the universe starts to write memories through bonds.
So let's just say there's rocks running around.
When the bond happens and selection starts, suddenly, the universe is remembering
cause and in the past.
And those structures will have effects in the future.
So suddenly a new type of time emerges at that point,
which has a direction.
And I think Sean Carroll at this point
might even turn the podcast back on.
I go, okay, I can deal with that, that's fine.
But I'm just basically trying to condense the conversation
and say, hey, let's just have time fundamental
and see how that screws with people's minds.
Why are you triggering people by saying fundamental?
Why not? We just say like let's say why look I'm walking through the wall. Why why should I?
Grow up in a world where time I don't go back in time. I don't mean I don't meet myself in the past
There are no one there are no aliens coming from the future
You know it's like here. Oh, no, no, no, no, no, no, no, no, no, no, no, no.
I'm not gonna say that.
That's like saying we're talking about biology or like evolutionary psychology and you're
saying, okay, let's just assume that that clothing is fundamental.
People wearing clothes is fundamental.
It's like, no, no, no, no, wait a minute.
You can't, like, I think you're getting in a lot of trouble if you assume time is fundamental.
Why?
Give me one reason why I'm getting into trouble time in fundamental.
Because you might not understand the origins of this memory that might be deeper.
Like that, this memory, that could be a thing that's explaining the construction of these
higher complexities better than just saying it's a search.
It's chemicals doing a search for reusable structures
that they can like then use as bricks to build a house.
Okay, so I accept that.
So let's go back a second because it's a kind of, I wanted to drop the time bomb at
this part because I think we can carry on discussing it for many, many, many, many,
many days, many months.
But I'm happy to accept that it might be wrong.
But what I would like to do is imagine a universe where time is fundamental and time is emerging. And ask, let's just then talk about causation.
Because physicists require that causation, so this is where I'm going to go.
Causation emerges, and it doesn't exist at the microscope.
Well, that clearly is wrong.
Because if causation has to emerge at the microscope, life cannot emerge.
So how does life emerge?
Life requires molecules
to bump into each other, produce replicators. Those replicators need to produce polymers.
There needs to be cause and effect at the molecular level. There needs to be an non-aguric to
an ageric transition, at some point. And those replicators have consequence, material
consequence in the universe.
Physicians just say, oh, you know what? I'm going to have a bunch of particles in the box.
I'm going to think about it in a Newtonian way and a quantum way, and I'll add on an arrow time
so I can label things. And causation will happen magically later. Well, how? Explain causation.
And they can't. The only way I can reconcile causation
is having a fundamental time, because this allows me to have a deterministic universe that
is creates novelty. And there's so many things from unpack here, but let's go back to the
point. You said, does it kind of assembly theory work with immersion time? Sure, it can,
but it doesn't give me a deep satisfaction
about how causation and assembly gives rise to these objects that move through time and
space. And again, what am I saying to bring it back? I can say, without fear, take this
water bottle, and look at this water bottle, look at the features on it, there's writing,
you've got a load of them. I know that causal structures gave rise to this.
In fact, I'm not looking at just one water bottle here.
I'm looking at every water bottle that's ever been conceived of by humanity.
This here is a special object.
In fact, Leibniz knew this.
You know, Leibniz was at the same time as Newton.
He kind of got stuck.
I think Leibniz actually invented assembly theory.
He gave soul. The soul that you see in objects
wasn't the mystical soul, it is assembly.
It is a fact there's been a history of objects related.
And without the object in the past,
this object wouldn't exist.
There is a lineage and there is conserved structures,
causal structures have given rise to those.
Fair enough.
And you're saying it's just a simpler view of time.
It's fundamental.
And it shakes the physicist's cage a bit, right?
Because I'm gonna say, but I think that...
I just enjoy the fact that physicists are encasers.
The secret is...
I think that, I would say that, you know, Lee Smolin, I don't want to speak for Lee,
I'm talking to Lee about this.
I think Lee also isn't agreement that time
has to be fundamental, but I think he goes further, you know,
even in space, I don't think you can go back
to the same place in space.
I've been to Austin a few times now,
as it's my, I think third time I've been to Austin,
is Austin in the same place?
No, the solar system is moving through space.
I've not been back in the same space.
Locally, I am.
Every event in the universe is unique.
In space.
At time.
At time.
Doesn't mean we can't go back though.
I mean, let's just, you know, rest this conversation,
which was a beautiful, with a quote from the Rolling Stones
that you can't always get what you want,
which is you want time to be fundamental,
but if you try, you'll get what you need,
which is assembly theory.
Okay, let me ask you about continuing talking about complexity and to clarify it with this
beautiful theory of yours that you're developing and I'm sure we'll continue developing both
in the lab and in theory.
Yeah, it can't be said enough, just the ideas you're playing with it in your head are just
and we've been
talking about it just beautiful. So if we talk about complexity a little bit
more generally, maybe in an admiring romantic way, how does complexity emerge
from simple rules? The why, the how? Okay, the nice algorithm of assembly is
there. I would say that the problem I have right now is, I mean, you're right, we can about time as well.
The problem is I have this hammer called assembly and everything I see is a nail.
So now let's just apply it to all sorts of things.
We take the Bernard instability.
The Bernard instability is, you can have oil, if you heat up oil, the sale of frying pan,
when you get convection, you get honeycomb patterns.
Take the formation of snowflakes, right?
Take the emergence of a tropical storm,
or the storm on Jupiter.
When people say, let's talk about complexity in general,
what they're saying is,
let's take this collection of objects
that are correlated in some way and try and work out
how many moving parts of how this got, how this exists.
So what people have been doing for a very long time is taking complexity and counting what they've lost,
calculating the entropy.
And the reason why I'm pushing very hard on assembly is entropy tells you how much you've lost.
It doesn't tell you the microstates are gone. And the reason why I'm pushing very hard on assembly is entropy tells you how much you've lost.
It doesn't tell you the micro-states are gone.
But if you embrace the bottom up of the assembly,
those states, you then understand the causal chain
that gives rise to the emergence.
So what I think assembly will help us do
is understand weak emergence at the very least,
and maybe allow us to crack open
complexity in a new way. And I've been fascinated with complexity theory for many
years. I mean, as soon as I could, you know, I learned of the Mandelbrot set and I
could write, write, it's just type it up in my computer and run it and just show
it and see it kind of unfold. It was just this kind of this mathematical reality that existed in front of me.
I just found incredible.
But then I realized that actually we were cheating.
We're putting in the boundary conditions all the time.
We're putting in information.
And so when people talk to me about the complexity of things, I say, but relative what, how do you measure them?
So my attempt, my small attempt, naive attempt, because there's many greater minds than mine on the planet right now thinking about this properly,
and you've had some of them on the podcast, right? Just absolutely fantastic.
But I'm wondering if we might be able to reformat the way we would explore
can algorithmic complexity using assembly.
Let's want some minimum number of constraints we need in our system for this to unfold.
So whether it's like, you know, if you take some particles and put them in a box,
at a certain box size, you get quasi-crystallinity coming out, right? But that
quite, that emergence, it's not magic, it must come from the boundary conditions you
put in. So all I'm saying is a lot of the complexity that we see is a direct read of
the constraints we put in, but we just don't understand. So as I said earlier, to the
poor origin of life, chemists, you know, origin of life is a scam.
I would say it locks the complexity calculation theory is a bit of a scam,
because we put the constraints in, but we don't count them correctly.
And I'm wondering if-
Oh, you're thinking in, so I'm going to drop,
is a assembly theory, something index is a way to call to the constraints.
Yes, that's it. It's all it is.
So assembly theory doesn't do, doesn't lower any of the importance of complexity theory,
but it allows us to go across domains and start to compare things, compare the complexity
of a molecule, of a microprocessor, of the texture of writing, of the music you may compose.
You've tweeted, quote, assembly theory explains why Nietzsche understood we had limited
freedom rather than radical freedom. So we've applied assembly theory to sell your automata
in life and chemistry. What does Nietzsche have to do with the assembly? Oh, that gets me
into free will when everything. So let me say that again, some Ethereum explains why Nietzsche understood we had limited
freedom rather than radical freedom, limited freedom, freedom I suppose is referring to the
fact that there's constraints.
Or what is radical freedom?
What is freedom?
So, Sasha was like believed in absolute freedom and that he could do whatever he wanted in his imagination.
And it's understood that his freedom was somewhat more limited.
And it kind of takes me back to this computer game that I played when I was 10.
So I think it's called Dragon's Lair.
Okay.
Do you know Dragon's Lair?
I think I know Dragon's Lair.
Yeah.
Dragon's Lair, I knew I was being conned, right?
Dragon Slayer, when you play the game,
you're lucky that you grew up in
a basically procedurally generated worlds.
Those RPG a little bit, no, it's a turn-based play,
was it?
No, it was a role-playing game,
but really good graphics, and one the first laser discs.
And when you actually flick the stick,
you took, it's like it was like a graphical adventure game with animation.
Yeah.
And when I played this game, I really, you know, you could get through the game in 12 minutes.
If you knew what you were doing, not making mistakes, just play the disc, play the disc.
So it was just that timing.
And as you was a complete fraud, because all the animation has been pre-recorded on the
disc.
Yeah.
It's like the Black Mirror, the first interactive, where they had all the, you know,
several million kind of permutations of the movie
that you could select on Netflix.
I forgot in the name of it.
So this was exactly that in the Laserdisc.
You basically go left, go right, fight the yoga,
slay the dragon, and when you flick the joystick
at the right time, it just goes
to the next animation to play.
It's not really generating it. And I play that game and I knew I was being
had. So, okay, I said see. So, to you, dragging there is the first time you realized that
free was an illusion. Yeah. And why there's assembly theory give you hints about free world whether it's an illusion or not.
Yeah, so no, so not tightly,
if I do think I have some will
and I think I am an agent
and I think I can interact
and I can play around with the models
I have of the world and the cost functions, right?
And I can hack my own cost functions,
which means I have a little bit of free will.
But as much as I want to do stuff in the universe,
I don't think I could suddenly say, I mean, actually, this is ridiculous, because now I say I could try and do it, right?
It's like, I'm suddenly give up everything and become a rapper tomorrow, right? Maybe I could
try that, but I don't have sufficient agency to make that necessarily happen. I'm on a
trajectory. So when in Dragon's Lay, I know that I have some trajectories that I can play
with where Sartre realized heories that I can play with, where
Sartre realized he thought that he had no assembly, no memory, he could just leap across
and do everything.
And Nietzsche said, okay, I realize I don't have full freedom, but I have some freedom.
And the 70th theory basically says that, says, if you have these constraints in your past,
they limit what you were able to do in the future,
but you can use them to do amazing things.
Let's say I'm a poppy plant, and I'm creating some opiates.
Opiates are really interesting molecules.
I mean, they're obviously great for medicine,
great problems, goals, great problems in society,
but let's imagine we fast forward a billion years.
What will the opiates look like in a billion years?
Well, we can guess because we can see how those proteins will evolve
and we can see how the secondary metabolites will change.
But they can't go radical.
They can't suddenly become, I don't know, like a molecule that you find in an OLED in a display.
They will be limited by the causal chain that produced them. And that's what I'm getting at, saying, you're, we're
predictive, we are unpredictably predictable or predictably unpredictable,
predictably unpredictable, predictably unpredictable within a constraint on
the trajectory we're on.
Yeah, so the predictably part is the constraints of the
trajectory and the unpredictable part is the part that you still haven't
really clarified the origin of, of the little and the unpredictable part is the part that you still haven't really clarified
the origin of the little bit of freedom. Yeah. So you're just arguing, you're basically saying that
the radical freedom is impossible. You're really operating in the world of constraints that are
constrained by the memory of the trajectory of the chemistry that led to who you are. Okay, but
trajectory of the chemistry that led to who you are. Okay. But, uh, you know, even just a tiny bit of freedom, even if everything, if everywhere you are in cages, if you can
move around in that cage a little bit, you're free. I agree. And so the question is, in
assembly theory, if we're thinking about free will,
where does the little bit of freedom come from?
What is the eye they can decide to be a rapper?
What?
Why?
What is that?
That's a cute little trick we've convinced each other out.
So we can do fun tricks at parties or is there something from the mental that allows us to feel free to be free?
I think that that's the question that I want to answer. I know you want to answer it and I think
it's so profound. Let me have a go at it. I would say that I don't take the stance of Sam Harris
because I think Sam Harris, when he said the way he says it, is almost, it's really interesting.
I'd love to talk to him about it. Sam Harris almost thinks himself out of existence, right?
So, no, I don't. Do you know what I mean?
Yeah, well, I mean, he has different views on consciousness versus fee will.
I think he saves himself with consciousness.
He thinks himself out of existence with free will.
Yeah, yeah, exactly. So, that mean there's no point, right?
So, he's a leaf floating on a river.
Yeah.
I think that he, he's, I don't know, I'd love to ask him
whether he really believes that
and then we could play some game.
Oh, yeah.
No, no, I'd then say I'd get him to play a game
of cards with me and I'll work out the conditions
on which he says no.
And then I'll get him to the conditions he says yes
and then I'll trap him in his logical inconsistency
with that argument
Because at some point when he loses enough money or you the prospect of losing enough money
There's a way of basically mapping out a series of so what what what will is about?
There's not for call it free will that what will is about is to have a series of
Decisions equally weighted in front of you. And those decisions
aren't necessarily energy minimization, those decisions are a function of the model you've
made in your mind, you're in your simulation. And the way you've interacted in reality,
and also other interactions that you're having with other individuals and happenstance. And I think that you, there's a little bit of delay in time.
So I think what you're able to do is say,
well, I'm going to do the counterfactual.
I've done all of them.
And I'm going to go this way.
And you probably don't know why.
I think free will is actually very complex interaction
between your conscious, your unconscious and your conscious brain. And I think the reason why we're
arguing about it is so interesting. In that, we just, some people outsource their free
will to that unconscious brain. And some people try and overthink the free will in the conscious
brain. I would say that Sam Harris has realized his conscious brain doesn't have free will, but his unconscious brain does. That's my guess, right?
And then he can't have access to the unconscious brain.
Yeah, and that's kind of annoying. And, but that's...
So he's just, he's going through meditation, contact acceptance with that fact.
Yeah, it's just, it's just maybe okay. I'm maybe, but I do think that I have the ability to make
decisions, and I like my decisions. In fact, I mean,
this is an argument I have with some people that some days I feel I have no free will and
it's just an illusion. And this is one that and it makes me more radical, if you like,
you know, as a, I get to explore more of a state space and I'm like, I'm going to try
and affect the world now. I'm really going gonna ask the question that maybe I dare not ask or do the thing I dare not do,
and that allows me to kind of explore more.
It's funny that if you truly accept
that there's no free will,
that is a kind of radical freedom.
It's funny, but you're,
because the little bit of the illusion in under that framework that you have that you can make choices
If choice is just an illusion of psychology, you can do whatever the hell you want
That's the but we don't do we and I think but because you don't truly accept that you you think that there's
Like you think there's a, which is why you don't just do whatever the
how you want. Like, you feel like there's some responsibility for making the wrong choice,
which is why you don't do it. But if you truly accept that the choice has already been made,
then you can go, I don't know, what is the most radical thing. I mean, but I don't, I wonder what,
what am I preventing myself from doing that I would really want to do?
Probably like humor stuff.
Like I would, I would love to, if I could like save a game,
do the thing and then reload it later, like do undo,
it'd probably be humor.
Just to do something like super hilarious.
That's super embarrassing and then just go, I mean, it's basically just fun.
I would add more fun to the world.
I mean, I sometimes do that.
I sometimes, I try and mess up my reality in unusual ways
by just doing things because I'm bored, but not bored.
I'm not expressing this very well.
I think that this is a really interesting problem
that perhaps the hard sciences don't really understand
that they have a responsible for
because the question about how life emerged
and how intelligence emerged
and consciousness and free will,
they're all ultimately boiling down
to some of the same mechanics, I think.
My feeling is that they are the same problem again and again and again.
The transition from a, you know, a boring world or a world in which there is no selection.
So I wonder free will has something to do with selection and models and also the models
you're generating the brain and also your, the amount of memory, the working memory have
available any one time to generate counterfactuals.
Well, this fascinating sort of like the decision making process is a kind of selection.
Yeah.
And that could be just absolutely yet another, yet another manifestation of the selection
mechanism that's pervasive throughout the universe.
Okay.
That's fascinating to think about.
Yeah.
There's not some kind of fundamental its own thing or something
like that that is just yet another example of selection.
Yeah. And in the universe that's intrinsically open, you want to do that because you generate
novelty. You mentioned something about do cellular
automata exist outside the human mind in our little offline conversation.
Why is that an interesting question?
So cellular atomic complexity, what's the relationship between complexity and the human mind and
trees falling in the forest?
Infrastructure.
So the CA, so when John von Neumann and Conway and Feynman were doing CA, they were doing
on paper.
CA is cellular atomic. just drawing them on paper.
How awesome is that that they were doing cellular atomic on paper?
Yeah.
And then they were doing a computer that takes like forever to print out anything and program.
Sure.
People are not with the TikTok kids these days with the TikTok.
Don't understand how amazing it is to just play with cellular
automata, arbitrarily changing the rules as you want to the initial conditions and see
the beautiful patterns emerge, sing with fractals, all of them.
Oh, I've got it all.
You've just given me a brilliant idea.
I wonder if there's a TikTok account that's just dedicated to putting out CA rules.
Isn't we should make one?
100%.
And that will get millions of views. Millions. Yes. No, it'll get
it'll get dozens. But just have them running. I'm so, look, I kind of
see a, I love CAs. Sorry. Yeah, no, I just have to make one. I actually, a few years ago,
I made some robots that talked to each other, chemical robots that played the game of Hex invented by John Nash, by doing chemistry,
and they communicated via Twitter, which were experiments they were doing. They had a
look-up table of experiments. Robot 1 said, I'm doing experiment 10, and the other is
robot, okay, I'll do experiment 1 then.
And they communicated via Twitter.
And then? And then. And then, publicly, yeah, yeah, yeah, yeah, yeah.
Yeah, yeah, yeah.
Can you maybe quickly explain what the game of Hexas?
Yeah, so it's basically a hexagonal board
and you try and basically, you color each element
on the board at each hexagon
and you try and get from one side to the other
and the other one tries to block you.
We are how really connected.
So what the robot, it's a chemical. Yeah, let's go back.
So the two robots, each robot was doing die chemistry. So making RGB red, green, blue, red,
green, blue, red, green, blue, and they could just choose from experiments to do red, green, blue.
Initially, I said to my group, we need to make two chemical robots that play chess. And my
group was like, there's too hard. No, Go away. But anyways, we had the right ball.
Go away.
But people listening to this should probably know that Lee
Cronin is a amazing group of brilliant people.
He's exceptionally well published.
He's written a huge number of amazing papers.
Whenever he calls himself stupid and is a sign of humility and I deeply respect
that and appreciate it. So people listening to this should know this is a world class
scientist who doesn't take himself seriously which I really appreciate and love. Any who
you talk about serious science, we're back to your group projecting your idea of chemical robots playing chess via dice.
So you want a simpler game of hacks.
Okay.
So what else?
The team that did it with Brilliant, I really think they still have PTSD from doing it
because I said, this is a workshop.
What I'd often do is I have about 60 people on my team. And occasionally before lockdown, I would say, I'm bit bored, we're going to
have a workshop on something. Who wants to come? And then basically about 20 people turn
up to my office and I say, we're going to do this mad thing. And then it would just
self-organize. And some of them would say, no, I'm not doing this. And then you get
left with the happy dozen. And what we did is we built this robot and doing die chemistry is really easy.
You can just take two molecules,
react them together and change color.
And what I wanted to do is have a palette
of different molecules,
you could react combinatorially and get different colors.
So you got two robots.
And I wouldn't it be cool if the robots basically shared
the same list of reactions to do.
And they said,
oh, I'm, and then you could do a call in multi-core chemistry.
Like they weren't, so you have two chemical reactions
going on at once.
And they could basically outsource the problem.
But they're sharing the same tape.
Exactly.
So robot mom would say, I'm gonna do,
I'm gonna do experiment one,
then the other robot says, I'll do experiment 100.
And then they coat, they cross it off,
but I wanted to make it go.
That's brilliant, by the way.
That is genius. So I wanted to make it gruv That's brilliant, by the way. That is genius.
Well, I wanted to make it gruvia and I said, look, let's have them competing to make,
to playing a game of hex.
And so when the robot doesn't experiment and the more blue the die, the higher chance
it gets to make the move it wants on the hex board.
So if it gets a red color, it's like it gets down weighted in the other robot.
And so what the robots could do is they play each player move
and cause the fitness function
or the optimization function was to make the color blue.
They started to invent reactions.
We weren't on the list.
And they did this by not cleaning,
because we made cleaning optional.
So when one robot realized, if it didn't clean its pipes,
it could get blue more quickly.
And the other robot realized that,
so it was like getting dirty as well.
And they, they, they,
I didn't do the consequences of super intelligence.
Okay.
But that was the game.
And we, we put a communique into Twitter though.
They were, they were doing it through Twitter and Twitter
bland them a couple of times.
I said, come on, you got a couple of robots doing chemistry.
It's really cool. It's not banning them. But, and then in the end, they had, we had to take them off Twitter and they just them a couple of times. I said, come on, you've got a couple of robots doing chemistry, it's really cool. It's not banning them. But in the end, we had
to take them off Twitter and they just communicated via a server because there were people saying,
you can still find it, Cronin Lab 1 and Cronin Lab 2 on Twitter. It was like make move, wait,
mix A and B, wait 10 seconds, you know. I really find it super compelling that you would have a chemical entity that's communicating
with the world.
That was one of the things I want to do in my origin of life reaction, right?
Is basically have a have a reactor that's basically just randomly enumerating through
chemical space and have some kind of cycle.
And then read out what the molecule's reading out
using a mass spectrometer.
And then convert that to text and publish it on Twitter.
And then wait until it says I'm alive.
I reckon that that Twitter account
will get a lot of followers.
Yeah.
And I'm still trying to convince my group
that we should just make an origin of life Twitter account.
Where it's going blue, blue, blue, blue, blue, blue.
And it's like, hello, testing.
I'm here. Well, I'll share it. I like work. I've had a lot of hard work. I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work.
I've had a lot of hard work. I've had a lot of hard work. I've had a lot of hard work. I've had a lot of hard work. Yeah. How we were talking about C.A.'s existing
outside of human mind.
Yeah.
So I really admire Stephen Wolfram.
I think he was a genius, clearly a genius.
And Traptin is actually, it's like a problem
with being so smart, if you get trapped in your own mind,
right?
And I tried to actually, I tried to convince Stephen
that Sembrithe was nonsense.
He was like, no, it's just nonsense.
I was a little bit sad by that.
So, nonsense applied, even if it applied to the simple cut.
Well, I was asked about a one-dimensional cellular diameter, for example.
Yeah, yeah. Well, I mean, actually, maybe I'm doing myself a bit too down.
It was just as a theory was coming through, and I didn't really know how to explain it.
But we are going to use SembritheerianAs, instead of Automata, but I wanted to,
what I was really curious about is why people are marvel,
I mean, you marvel CAs and they're complex,
and I said, well, hang on, that complexity's baked in,
because if you play the game of life in a CA,
you have to run it on a computer.
You have to have a, you have to do a number of operations,
put in the boundary
conditions. So is it surprising that you get this structure out? Isn't manufactured by
the boundary conditions? And, and it is interesting because I think a set, a set of automata running
them is teaching me something about what real numbers are and aren't. And I haven't quite
got there yet. I was playing on the error plane coming over.
I'm just realizing I have no idea what real numbers are,
really.
And I was like, well, I do actually have some notion
of what real numbers are.
And I think thinking about real numbers
as functions rather than numbers is more appropriate.
And then if you then apply that to CAs,
then you're saying, well, actually, why am I saying this
complexity in this rule? Is it, you know, is it, is it, is it, is it, you've got this deterministic
system? And yet you get this incredible structure coming out. Well, isn't that what you'd get with
any real number as you, as you apply it as a function? And you you try to read it out to an arbitrary position.
And I wonder if CAs are just helping me, well, my misunderstanding is CAs, might be helping me
understand them in terms of real numbers. I don't know what you think. Yeah, well, the func-
but the devil's in the function. Mm-hmm. Like, which is the function that's generating your real
like, which is the function that's generating your real number?
Like that, it seems like it's very important, the specific algorithm that function because some lead to something super trivial,
some lead to something that's okay,
I think in some lead to things that are just walked
at fine line of complexity and structure.
I think we agree.
So let's take it back a second. So take the logistic map or something, logistic
equation. Where you have this equation, which is, you don't know what's going to happen
at M plus 1, but once you've done M plus 1, you know, for all time, you can't predict it.
For me, C.A. is a logistic equation, feel similar. And I think what's incredibly interesting,
and I share your kind of wonder at running a CA,
but also I'm saying, well, what is it
about the boundary conditions
and the way I'm running that calculation?
So in my group, with my team, we actually made a chemical CA.
We made game of life.
We actually made a physical grid.
I haven't been out of publishers' papers,
been trapped in purgatory for a long time,
but it might not be a paper had to do a chemical formulation
of the game of life, which is a way.
We made a chemical computer and little cells.
And I was playing Game of Life.
With the Boot BZ reactions, each cell would pulse on and off,
on and off, on and off.
We have little stirrabars and we have little gates.
And we actually played Conway's Game of Life in there and we got structures in that
We got structures in that game from the chemistry that you wouldn't expect from the actual CA
So that's kind of cool in that um because they're they're they're interacting outside of the cell smell or so what's happening is you're getting
No, so the thing is that you've got this BZ reaction, it gives on off, on off, on off, but there's also awake. And those wakes constructively interfere
or it's such a non-trivial way that it's a non-deterministic and the non-determinism in
the system gives very rich dynamics. And I was wondering if I could physically make a chemical computer with this
CA that gives me something different. I can't get in a silicon representation of a CA where all
the states are clean because you don't have the noise trailing into the next round. You just have
the state. So the paper in particular, so just a beautiful idea to use a chemical computer
to construct a cellular tamar and the famous one of Game of Life, but it's also interesting
and it's really interesting scientific question of whether some kind of random perturbations
or some source of randomness can have a significant constructive effect on the complexity of the system.
And indeed, whether it's random or just non-deterministic and can we bake in that non-determinism at the beginning,
I'm trying to think about what is the encoding space? The encoding space is pretty big. We have 49 stars of 49 cells,
49 chem bits, all connected to one another in an analog computer, but being read out
discreetly as the BZ reaction. So just to say the BZ reaction is a chemical oscillator.
And what happened in each cell is it goes between red and blue. So two Russians discovered it,
the loose-off Sapaskynski.
I think the lose off first proposed it,
and everyone said, you're crazy, it breaks a second law.
And Sapasky said, no, it doesn't break the second law,
it's consuming a fuel.
And so, and then, and it's a, like,
there's a lot of chemistry hidden in the Russian literature, actually,
because Russians just wrote it in Russian,
they didn't publish it, and you're speaking German.
It's a heartbreaking, actually. Well, it's, they didn't publish it English, speaking German.
That's probably breaking actually.
Well, it's sad and it's great that it's there, right?
It's not lost.
I'm sure we will find a way of translating it properly.
Well, the silver lining slash grade or sadness of all of this is there's probably ideas
in English speaking.
Like, there's ideas in certain disciplines that if discovered by other
disciplines would crack open some of the biggest mysteries in those disciplines.
Like computer science, for example, is trying to solve problems like nobody else has ever
tried to solve problems.
As if it's not already been all addressed in cognitive science, in psychology, mathematics,
in physics, in whatever you want, economics even.
But if you look into that literature,
you may be able to discover some beautiful ideas.
Obviously, Russian is an interesting case of that
because there's a loss in translation,
but you said there's a source of fuel, a source of energy.
Yeah, yeah, so the BZ reaction,
you have an acid in there called melonic acid.
Yeah.
And what happens is when it root,
power is basically like a battery that powers it,
and it loses CO2, so decubox, it's just a chemical reaction.
What that means we have to do is continuously feed,
or we just keep the BZ reaction going in a long enough time. So it's like it's reversible in time.
But only like, yeah. But it's fascinating. I mean, the team that did it, I'm really proud of
their persistence. We made a chemical computer. It can solve little problems. It can solve
traveling salesman problems, actually. But like I problems, it can solve traveling salesman problems actually.
Nice. But like I say it's, it's a nice, fast, and then the regular computer. Is there something
you can do? Maybe. I'm not sure. I think we can come up with a way of solving problems,
also really complex hard ones, because it's an analog computer and we can, we can, the, it can
energy minimise really quickly. It doesn't have to basically go through every
element in the matrix, like flip it, it reads out. So we can actually do Monte Carlo
by just shaking the box. It's literally a box shaker. You don't actually have
to encode the shaking of the box and a silicon memory and then just shuffle everything around. Yeah, and you can sound a lot of it. It's natural
so it's an organic computer. Yeah, yeah. So I was playing around with this and I was
kind of annoying some of my colleagues. I was wondering if we could get to chemical
supremacy, like quantum supremacy. And I kind of calculated how big the grid has to be
so we can actually start to solve problems faster
than a silicon computer.
But I'm not willing to state how that is yet,
because I'm probably wrong.
It's not that I'm, it's any top secret thing,
is I want, I think I can make a chemical computer
that can solve optimization problems
faster than a silicon computer.
That's fascinating.
But then you're unsure how big that has to be.
Yeah, I think I mean,
it might be a big box, hard to shake.
It might be exactly a big box, hard to shake
and basically a bit sloppy.
Did we answer the question about
do cellular time exist outside the mind?
We didn't, but I would, I would pause it that they don't.
And I, and, but I think minds can posit that they don't and I and but I think minds can well.
So the mind is fundamental.
What's the what I mean?
Well, I mean, sorry, let's just go back.
So as a physical phenomena, do CAs exist in physical reality?
Right.
I would say they probably don't exist outside the human mind, but now we've
constructed them.
They exist in computer memories.
They exist in my lab.
They exist on paper. So they are they emerge from the human mind, but now we've constructed them, they exist in computer memories, they exist in my lab, they exist on paper. So they are, they emerge from the human mind. I'm
just interested in, because Stephen Wolfram likes CAs, a lot of people like CAs, likes to
think of them as minimal computational elements. I'm just saying, well, do they exist
in reality, or they are representation of a simple machine that's just very elegant to
implement? system reality or they are representation of a simple machine that's just very elegant to implement. So there's a platonic question, I guess.
I mean, there's initial conditions, there's a memory in the system.
There's simple rules that dictate the evolution of the system.
So what exists, the idea, the rules, the...
Yeah.
People are using CA's as models for things in reality to say, hey, look, you
can do this thing in a C.A. And when I see this, I'm saying, oh, that's cool. But what does
that tell me about reality? Where's the C.A. And space by C. That's right. It's a mathematical
object. So for people who don't know cellular automata, there's usually a grid where there's
one dimension or two to two dimensional or three dimensional.
And it evolves by simple local rules.
Like you die or are born if the neighbors are alive or dead.
And it turns out if you have with certain kinds
of initial conditions and with certain kinds
of very simple rules, you can create
like arbitrarily complex and beautiful systems and to me
You know whether drugs are involved or not. I can sit back for hours and enjoy the
The mystery of it how such complexity can emerge is it gives me almost like you know people talk about religious experiences It gives me almost like, you know, people talk about religious experiences, it
gives me a sense that you get to have a glimpse at the origin of this whole thing.
Whatever is creating this complexity from such simplicity is the very thing that brought my mind to life, that's me, the human,
our human civilization.
And yes, those constructs are pretty trivial.
I mean, that's part of their magic is even in this trivial framework, you could see
the emergence, or especially in this trivial framework, you could see the emergence, or especially in this trivial
framework, you could see the emergence of complexity from simplicity.
I guess what Lee you're saying is that this is not highly unlike systems we've seen
in the physical world, even though they probably carry some of the same
magic, like mechanistically. I mean, I'm saying that the operating system that a CA has to exist on is quite complex. And so I wonder if you're getting the complexity out of the CA
from the boundary conditions, the operating system, the underlying digital computer.
Oh, wow. Those are some strong words against the A's then.
Not again, I mean, I mean, I'm in love with CAs as well.
I'm just saying they aren't as trivial as people think.
They are incredible.
To get to that richness, you have to iterate billions of times.
And you need a display, and you need a math coprocessor,
and you need a funnoyment machine
based on a churring machine with digital error correction and states.
Wow.
To think that for the simplicity of a grid, you're basically saying a grid is not simple.
Yeah.
It requires incredible complexity to bring a grid to life.
Yeah.
Yeah.
Yeah.
That's what I'd then what is simple.
That's all I want to say.
I agree with you with a wonder of CAs.
I just think, but remember, we take so much for granted,
well, the CAs resting on, because von Neumann and Feynman
weren't showing, weren't seeing these elaborate structures.
They could not get that far.
Yeah, but that's the limitation of their mind.
Yeah, yeah, exactly.
They don't know. They're pencil. But I think that's the limitation of their mind. Yeah, exactly. The limitation of their pencil.
But I think that's the question is whether the essential elements of the cellular
tomat is present without all the complexities required to build a computer.
And my intuition, the reason I find it incredible is that incredible is that my intuition is yes. If I look different,
there might not be a grid structure, but local interactions operating under simple rules
and resulting in multi-hierarchical complex structures feels like a thing that doesn't require a computer.
I agree, but coming back to von Neumann and Feynman and Wolfram, they're minds, the non-trivial
minds, to create those architectures and do it and to put on those state transitions.
And I think that something that's really incredibly interesting, that is understanding how the
human mind builds so straight, those state transition machines.
I could see how deeply in love with the idea of memory you are.
So it's like, how much of E equals MC squared?
Like is more than an equation, It has Albert Einstein in it. Like you're saying like you
can't just say this is a like the equations of physics are a really good simple
capture of a physical phenomena. It is also has the memory that equation has the
memory of the humans. Absolutely. Yeah.
Absolutely.
Yeah.
But I don't, I don't know if you're implying this,
I don't, that's a beautiful idea,
but I don't know if I'm comfortable with that,
sort of diminishing the power of that equation.
No, no, it enhances it.
Because it's not on the shoulders, it enhances it.
I think it enhances it.
It's not, that equation is a minimal compressed representation of reality, right? Yeah, we can use machine learning or or max
tag marks, AI Feynman to find lots of solutions for gravity. But isn't it wonderful that the laws that we do find are the maximally compressed representations.
Yeah, but that representation you can now give it as I guess the universe has the memory of Einstein with that representation. But then you can now give it as, I guess the universe has the memory of Einstein
with that representation,
but then you can now give it as a gift for free.
Yeah, yeah, it's all memory.
It's all memory.
I guess I have to go for a lot of pain to get there,
but it's low memory.
So I say that physics and chemistry and biology
are the same discipline.
They're just physics, laws in physics.
There's no such thing as a law in physics.
It's just low memory stuff.
Because you've got low memory stuff, you can things reoccur quickly. As you get building more memory,
you get to chemistry so things become more contingent. When you get to biology, more contingent
still and then technology. So the more memory you need, the more your laws are local. That's
all I'm saying. In that the less memory, the more the laws are universal because they're
not laws. They are just low memory states.
We have to talk about a thing you've kind of mentioned already a bunch of times, but doing computation through chemistry, chemical-based computation,
I've seen you refer to it as in a sexy title of camp mutation,
computation. So what is computation? What is chemical-based computation?
Okay, so computation is a name I gave to the process of building a state machine to make any molecule physically in the lab. And so, as a chemist, chemists make molecules by hand.
And they're quite hard.
They can chemists have a lot of tacit knowledge,
a lot of ambiguity.
It's not possible to go uniformity to literature and read a recipe to make a molecule
and then go and make it in the lab every time.
Some recipes are better than others, but they all assume some knowledge.
And it's not universal what that is.
Like so it's carried from, from human to human.
Yeah, some of that implicit knowledge.
And you're saying, can we remove the humor from the picture?
Can we like a program?
Okay.
Well, by the way, what is a state machine?
So a state machine is a, I suppose, a, a, a object, either abstract or mechanical,
where you can do, you can do a unit operation on it and flick it from one state to another.
So a turn style would be a good example of a state machine.
A, there's some kinds of states and some kind of transitions to states. And it's
very formal in nature in terms of precise how you do it. You've been mathematically
precisely describe a state machine. So I mean, you know, a very simple Boolean gates are a very
good way of building kind of logic-based state machines.
Obviously a cheering machine,
the concept of a cheering machine
where you have a tape and a read head
and a series of rules in a table
when you would basically look at what's on the tape
and if you're shifting the tape from left to right
and if you see a zero or one,
you look in your lookup table and say,
right, I've seen a zero and a one.
I then do, I then respond to that.
So the turn style would be, is there a human being pushing the turn style in direction
clockwise?
If yes, I will open, let them go.
If it's anti-clockwise, no.
So yes, so state machine has some labels and a transition diagram.
So you are looking to come up with a chemical computer to form state machines to create molecules
or what's the chicken and the egg?
So computation is not a chemical computer because we talked a few moments about actually doing
computations with chemicals.
What I'm now saying is I want to use state machines
to transform chemicals.
And so,
so build chemicals programmatically.
Yeah, I mean, I get in trouble saying this.
I said to my group, I shouldn't say it,
because this, but I said, look,
we should make the crackpot,
is in the crack robot.
The robot that makes crackpot.
The robot, oh, crackpot.
The robot that makes crack, but maybe we should scrub this from
or, well, so maybe you can educate me on breaking bad with like math. Yeah, so in breaking bad,
you want to make you want to make basically some kind of mix of X Markina and breaking bad.
No, I don't. I don't record, I don't, but I said,
you don't, I said that's what I'm going to do it once you release the papers.
But I shaved my head and I'm going to live a life of crime anyway, I'm sorry.
No, no, so, so yeah, let's go back to, so indeed it is about making drugs,
but importantly, making important drugs.
So let's-
All drugs matter.
Yeah, but let's go back.
So the basic thesis is chemistry is very analog.
There was no state machine.
And I wandered into the, through the paper walls
in the Japanese house a few years ago
and said, okay, hey, organic chemist, why are you doing this analog? They said, well, chemistry is really hard.
You can't automate it. It's impossible. Is it impossible? It says, yeah, they said,
they said, you know, I got the impression, they're saying it's magic. And so when people tell me
things are magic, it's like, no, no, they can't be magic. Right, so let's break this down. And so what I did is I went to my group one day
about about eight years ago and said,
hey guys, I've written this new programming language for you.
And so everything is clear.
And you know, you have to not allow to just wander around the lab.
Willie Nile, you have to pick up things in order,
go to the balance of the right time and all this stuff.
And they looked at me as if I was insane
and basically kicked me out of the lab and said, no, no don't do that we're not doing that yeah and I
said okay so I went back the next day and said I'm gonna find some money so we can make cool robots
to chemical reactions then one went that's cool yeah and so in that process the first
of tragedy convert the humans to become robots and next you agree to you might as well just create the robots.
Yes, but so in that in that the formalization process.
Yeah, so what I did is to look at chemical to make a molecule you need to do four things abstractly.
I want to make a chemical cheering machine because a cheering machine you it's been shown by cheering another's
that basically a universal cheering machine
should be able to do all computations
that you can imagine.
It's like, wow, why don't I think of a cheering machine
for chemistry?
Let's think of a magic robot that can make any molecule.
Let's think about that for a second.
Okay, great.
How do we then implement it?
And I think, right, so what is the abstraction?
So to do, to make any molecule, you have to do a reaction.
So you have to put reagents together to do a reaction in a flask, typically.
Then you're after the reaction, you have to stop the reaction.
So you do what's called a workup.
So whatever, call it down, add some liquid to it, extract.
So then after you do a workup, you separate.
So you then remove the molecule, separate them all out.
And then the final step is purification.
So reaction at workup, separate purify. So this is basically like my exactly like a
Turing machine where you have your tape, you have your tape head, you have some rules, and then you run it.
So I thought cool. I went to all the chemists and said, look, chemistry isn't that hard.
I went to all the chemists and said, look, chemistry isn't that hard. Reaction, workup, separation, purification.
Do that in cycles, forever, for any molecule, all the chemistry done.
And they said, chemistry is that hard.
I said, but just in principle, and I got a few very enlightened people to say, yeah, okay,
in principle, but it ain't going to work.
And this was in about 2013, 2014.
And I found myself going to an architecture conference,
almost by accident,
it's like, why am I at this random conference
on architecture?
And that was because I published a paper
on inorganic architecture.
And they said come to architecture conference,
but the inorganic architecture is not in architecture.
It's not, and I went, okay.
And then I found these guys at the conference,
3D printing, ping pong balls and shapes. And guys at the conference, 3D printing ping pong balls
and shapes and this is through it, 3D printing was cool and it's like, this is ridiculous,
why are you 3D printing ping pong balls? I gave them a whole load of abuse, like I normally do
when I first meet people, how to win friends and influence people. And then I was like, oh my god,
you guys are geniuses. And so I got, I got from, they were a bit confused because I was calling
them idiots and then called them geniuses. It's like, will you come to my lab and we're
going to build a robot to do chemistry with a 3D printer? And
this is, oh, that's cool. All right. So I had them come to the lab
and we started to 3D print test tubes. So you imagine, you know,
3D print a bottle and then and then and then used the same
gantry to basically rather than to square out a plastic
nozzle, have a little syringe and jump chemicals in.
So we had the 3D printer
because simultaneously print the test tube
and then put chemicals into the test tube.
And then,
well, that's really end to end.
Yeah, that's like,
that'll be because they've got G-code to do it all.
It's like, yeah, that's cool.
So I got my group doing this
and I developed it a bit
and I realized that we could take those unit operations
and we built a whole bunch of pumps and valves and I realized that I could take those unit operations and we built a whole bunch of pumps and valves
and I realized that I could basically take the literature and I made the first version
of the computer in 2016-17.
I made some architectural decisions so I designed the pumps and valves in my group.
I did all the electronics in my group.
They were brilliant.
I cannot pay tribute to my group enough in doing this.
They were just brilliant.
And there were some poor souls there that said, Lee, why are you making
this design electronics?
I'm like, well, because I don't understand it.
They're like, so you're making this design stuff because you don't understand.
It's like, yeah, it's like, but can we not just buy some?
I said, well, we can, but then I don't understand how to, you know,
what bus they're going to use and this serial ports and all this stuff.
I just wanted, and I
made, I came up the decision to design a bunch of pumps and
valves and use power of the ethernet. So they've got one cable
for power and data, plug them all in, plug them all into a
router, and, and then I made the state machine. And there was a
couple of cool things I did, all they did actually. We got the abstraction, so reaction, work up separation, I purification.
And then I made the decision to do it in batch.
Now it's in batch, all chemistry had been digitized before, apparently, it was
it was being done, but everyone's been doing it in flow.
And flow is continuous and there are infinities everywhere. And you have to just, and I realized that I could actually make a
state machine where I basically put stuff in the reactor, turn it up from one state to
another state, stop it, and just read it out. And okay, and I was kind of pitching it,
electrical engineers saying, you have it easy, you don't have to clean out the electrons,
you know, if you could, electrons don't leave a big mess, they leave some EM waste. But in my state machine, I built
in cleaning. So it's like, we do all operation, and then it cleans the backbone, then can do
it again. So there's no, so what we managed to do over a couple of years is, is develop the
hardware, develop state machine, and we encoded three molecules, we did three, the first
three, we did NITOL, was sleeping drug, ref we're finna myodantic seizure and Viagra.
You know, and I could make jokes on the paper,
it's a hard problem, blah, blah, blah.
That is very good.
And then in the next one, what we did is said,
okay, my poor organic chemist said,
look, Lee, we've worked with you this long,
we've made a robot that looks like it's gonna take
our jobs away and not just take our jobs away, that what we love in the lab, but now we
have to become programmers, but we're not even good programmers.
We just have to spend ages writing lines of code that are boring, and it's not
as elegant. I went, you're right.
So then, but I knew because I had this abstraction, and I knew that there was
language, I could suddenly develop a state machine
that would interpret the language which was lossy and ambiguous and populate my abstraction.
So I built a chemical programming language that is actually going to be recursively enumerable.
It's going to be a true and complete language which is kind of cool which means it's formally
very viable.
So where we are now is we can now read the literature using a bit of natural language processing.
It's not the best.
Many other groups have done better job, but we can use that language reading to populate
the state machine and basically add sub tractors.
We've got about a number of primitives that we basically program loops that we dovetail
together and we can make any molecule with it.
Okay, so that's a kind of program synthesis. So you start at like literally you talk about
like a paper, like a scientific paper that's being read. Yeah, natural English processing,
extracting some kind of details about chemical reactions and the chemical molecules of compounds involved. And that's that in
GPT terms, serves as a prompt for the program synthesis that's kind of trivial right now.
There you have a bunch of different like for loops and so on. That creates a program in this chemical language that can then be interpreted
by the chemical computer, the computer. Yeah, that's what it works. Yeah. Everything
sounds better in your British accent, but it's, I love it. So the, into the computer and
that's able to then basically be a 3D printer for these from molecules.
Yeah, I wouldn't call it a 3D printer.
I would call it a universal chemical reaction system because 3D printing gives the wrong impression.
But yeah, and it purifies.
And the nice thing is that that code now that we call it the kind of L code is really interesting because now,
so computation, what is computation?
Computation is what computing is to mathematics, I think.
Computation is the process of taking chemical code
and some input reagents and making the same molecule,
making the molecule reproducibly every time
without fail, what is computation?
It's the process of using a program
to take some input conditions
and give you an output, same every time, right?
We're reliably.
So the problem is,
now maybe you can push back and correct me on this.
So I know biology is messy.
My question is how messy is chemistry?
So if we use the analogy of a computer,
it's easier to make computation
in a computer very precise. That's repeatable. It makes errors almost never. It does the exact
thing we're over and over and over and over. What about chemistry? Is there a messiness in the whole
thing? It can that be somehow leveraged? Can that be control, can there be that removed, do we want to remove from the system?
Oh, yes and no, right.
This is a messiness.
There is messiness because chemistry is like,
you're doing reactions on billions of molecules
and they don't always work, but you've got purification there.
And so what we've found is at the beginning,
everyone said it can't work.
It's going to be too messy.
It will just fail. And I said, but you managed to get chemistry to work in the lab. You magic. You
do something. So I would say now go back to the first ever computer or the ENIAC. Five million
soldered joints, 400,000 files are exploding all the time. Was that? Would you have gone, okay, that's messy. So we've got the,
have we got the equivalent of the anti-ac in my lab? We've got 15 computers in the lab now.
And are they unreliable? Yeah, they fall apart here and there. But are they getting better?
Really quickly? Yeah. Are they now able to reliably make, are we at the point in the lab,
whether some molecules we would rather make on the computer than have a human being make? Yeah, we've just done, we've just made an
anti-influenza molecule, some antivirals, six steps on the computer that would take a human being
about one week to make arbodole, of continuous labor, and all they do now is load up the reagents, press go button,
and just go away and drink coffee.
Wow.
So this, I mean, and this is, you're saying
this computer's just the early days.
And so, like some of the criticism
just have to do with the early days.
And yes, I would say this something like this
is quite impossible.
You know, so the fact that you're doing this is incredible. Not impossible, of course, but
extremely difficult. It did seem really difficult and I do keep pinching myself when they go in the
lab. I was like, is it working? Yep. And it's not, you know, it does clog. It does stop.
You've got a clean. This is great. But it's getting more reliable because we just made design decisions and said
we are not going to abandon the abstraction. Think about it. If the von Neumann implementation
was abandoned, think about what we do to semiconductors to really constrain them, to what we do to
silicon in a fab lab. We take computation for granted. Silicon is not in its natural state.
We are doping the hell out of it.
It's incredible what they're able to accomplish
and achieve that reliability at the scale they do.
Like you said, that's after Moore's Law will have now.
And what we, you know, how it started, you know,
now we're here, we've started the bottom now we're here.
We have only have 20 million molecules,
well say 20 million molecules in one database,
maybe a few hundred million in all the pharmaceutical companies.
And those few hundred million molecules
are responsible for all the drugs
that we've had in humanity, except, you know,
biologics for the last 50 years.
Now imagine what happens when a drug goes out of print,
goes out of print, because there's only a finite number of manufacturing facilities in the
world that make these drugs. Yeah, that can keep you still printing press.
The chemistry. Yeah. And not only that, we can protect the KIDL so we can
stop bad actors doing it, we can encrypt them and we can give people life.
Yeah, that's the name of the surgeon, dropped as the name of the program in
language. Yeah, the KIDL is the name of the programming language
and the code we give the chemicals.
So Khi, as in, you know, just for,
it's like a, it's actually like an XML format,
but I've now taken it from script to a fully expressable
programming language so we can do dynamics
and there's four loops in there and conditional statements.
But the structure is started out as a,
like an XML thing. Yeah, yeah, yeah.
And now we also, the chemist doesn't need to program in KDL.
They can just go to the software and type in add A to B,
reflux, do what they would normally do.
And you just convert it to KDL
and they have a linter to check it.
In every correct way.
So how do you, you know, not with ASCII,
but because it's a Greek letter, how do you go with, how
do you spell it just using the English alphabet?
We're just, I-
X-D-L.
X-D-L, but we'll be used, we put in Kai.
And it was named by one of my students, and I, not one of my postdocs many years ago,
and I liked it.
It's like, it's important, I think, when the team are contributing to such big ideas,
because there are ideas as well, I try not to just rename it, I didn when the team are contributing to such big ideas, because there are ideas as well.
I try not to just rename it, I didn't call it cronin or anything that, because they keep saying,
you know, is a chemistry when they're putting stuff in the computer, one of my students said,
we're asking that, is it cronin complete?
And I was like, what does that mean?
And I said, well, can we make it on the damn machine?
And I was like, oh, is that a compliment or a majority of it?
But they're like, well, it might be better.
Yeah, so you tweeted, quote, why does chemistry need a universal programming language?
Question mark.
For all the reasons you can think of, reliability, interoperability, collaboration, remove ambiguity, lower cost, increased
safety, open up discovery, molecular customization, and publication of executable chemical code,
which is fascinating, by the way, just publish code.
And can you maybe elaborate a little bit more about this KIDL?
What does the universal language of chemistry look like?
A cron and complete language.
It's a cheering complete language, really.
But so what it has, it has a series of operators in it like ad,
heat, stir.
So there's a bunch of just unit operations. And all it is really is just,
it's with chemical engineers, my talked about this, that you've just rediscovered chemical
engineering. And I said, well, yeah, I know. I said, well, that's trivial. I said, well,
not really. Well, yes, it is trivial. And that's why it's good. Because we've not only if we
discovered rediscover discover chemical engineering,
we've made it implementable on the universal hardware
that doesn't cost very much money.
And so the KDL has a series of statements
like define the reactor.
So defines the reagents.
So they're all labels.
So you assign them.
And what I also implemented at the beginning
is because I give all the hardware IP address,
you put it on a graph. And so what it does is like the graph is equivalent to the process
of firmware, the processor code. So when you take your KDL and you go to run it on your computer,
you can run it on any compatible hardware and any configurations. What does your graph look like?
As long as I can solve the problem on the graph
with these unit operations,
you have the resources available at Compire,
Chem Piles. Ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, ah, okay, the problem we have before is it was possible to do robotics for chemistry,
but the robots were really expensive.
They were unique, they were vandalogged.
And what I want to do is to make sure
that every chemist in the world can get access
to machinery like this at virtually no cost
because it makes it safer.
It makes it more reliable.
And then if you go to the literature
and you find a molecule that could potentially cure
cancer.
And let's say the molecule that could potentially cure cancer takes you three years to repeat.
And maybe a student finishes their PhD in the time and they never get it back.
So it's really hard to kind of get all the way to that molecule and it limits the ability
of humanity to build on it. If I just download the code and can execute it, it turns, I would say the electronic laboratory notebook in chemistry is a data cemetery.
Because no one will ever reproduce it. But now the data cemetery is a duper to notebook and you can just execute it.
It can be a complete with it. Yeah, they access to it. Reverse, or is the magnitude is increased.
We'll talk about the, so as with all technologies,
I think there's way more exciting possibilities,
but there are also terrifying possibilities,
and we'll talk about all of them.
But let me just kind of linger on the machine learning
side of this.
So you're describing programming, but it's a language, I don't know if you've heard about OpenAI codex, which is
I'm playing with it.
Of course you are.
You really are Rick from Rick and Morty. This is great. Okay.
Except philosophically. I mean, he is, I guess, kind of philosophically deep to. So for people who don't know, GPT, GPT-3, it's a language model that can do natural
language generation. So you can give it a prompt and it can complete the rest of
it. But it turns out that that kind of prompt, it's not just completes the
rest of it, it's generating like novel sounding text,
and then you can apply that to generation of other kinds of stuff.
So these kinds of transformer-based language models
are really good at forming deep representations
of a particular space, like a medium, like language.
So you can then apply it to specific sub-to-language
like programming. So you can have it learn the representation of the Python
programming language and use it to then generate syntactically and
semantically correct programs. So you can start to make progress on one of the
hardest problems in computer science, which is program synthesis. How do you write programs that accomplish different tasks?
So what OpenAI codex does is it generates those programs based on a prompt or some kind.
Usually you can do a natural language prompt.
So basically, as you do when you program, you write some comment, which serves the basic documentation
of the inputs and the outputs and the function of the particular set of code, and it's
able to generate that.
The point being is you can generate programs using machine learning, using neural networks.
Those programs operate on the boring old computer.
Can you generate programs that operate,
this guy be a clever version of programs for this,
but can you write programs that operate on a computer?
Yep, there's actually software out there right now
and go and do it.
Really?
Yeah, it's a heuristic, it's rule based,
but we have what we've done inspired by codex,
actually, is over the summer, I ran a little workshop. Some of my groups thought this inspired
idea that we should get a load of students and ask them to manually collect data, to label
chemical procedures into KIDL. And we have a call synth reader.
So there's a lot of bunch of people doing this right now,
but they're doing it without abstraction.
And because we have an abstraction that's
implementable in the hardware,
we've developed basically a chemical analog of codex.
What we usually say is so to draw?
We say abstraction in the hardware, what do you mean?
So right now, a lot of people do a machine learning
and reading chemistry and just saying,
oh, you've got these operations, add, shake, whatever he,
but they, because they don't have a uniform,
I mean, a couple of groups doing it.
Competitors actually, they're good, very good.
But they can't run that code automatically.
They are losing meaning.
And the really important thing that you
have to do is generate context.
And so what we've learned to do with our abstraction
is make sure we can pull the context out of the text.
And so can we take a chemical procedure and read it and generate our executable code?
Yes.
What's the hardest part about that whole pipeline from the initial text interpreting
the initial text of a paper, extracting the meaningful context and the meaningful chemical
information to then generating the program, to then running
that program in the hardware. What's the hardest part about that pipeline as we look towards
a universal touring computer?
So, the hardest thing with the pipeline is the software, the model gets confused between some meanings.
So if chemists are very good at inventing words that aren't broken down,
so the classic word that you would use for boiling,
something is called reflux.
So reflux is, you would have a solvent in the round-bond flask,
at reflux it would be boiling, going up the reflux condenser and coming down.
But that term reflux, two reflux, could be changed, you know, to people often make up words,
new words, and then the software can fall over.
But what we've been able to do is a bit like in Python or any programming language, is
identify when things aren't matched.
So you present the code and
say, this isn't matched, you may want to think about this. And then the user goes and says,
oh, I mean reflux and just tick the box and flex it. So what the codex or the chemx does in
this case is it just, it suggests the first go and then the chemist goes and corrects it.
And I really want the chemist to correct it because it's not safe, I believe, for to allow AI to just read literature and generate code at this
stage. Because now you're having actual, by the way, chemics, nice, nice name. So you are unlike,
next name. So you you are unlike which is fascinating. It's that we live in a fascinating moment in human history. But yes, you're literally connecting AI to
some physical and like it's building something in the physical realm, especially in the space of chemistry that operates
sort of invisibly.
Yeah, I would say that's right.
And it's really important to understand those labeling schemes, right?
One of the things I was never, I was always worried about the beginning that the abstraction
was going to fall over.
And the way we did it was just by brute force to start with.
We just kept reading the literature and saying, is there anything new?
Can we have a new rule in?
And actually our KIDL language expand, exploded.
There was so many extra things we had to keep adding.
And then I realized the primitives still maintained.
I could break them down again.
So it's pretty good.
I mean, there are problems.
There are problems of, you know,
interpreting any big sentence
and turning it into an action or code.
And the codex is not without its problems.
You can crash it quite easily, right?
You can generate nonsense.
But boy, it's interesting.
I would love to learn to program now using codex, right?
Just hacking around, right?
And I wonder if chemists in the future
will learn to do chemistry by just hacking around, right? And I wonder if chemists in the future will learn to do chemistry
by just hacking around with the system writing in different things, because the key thing
that we're doing with chemistry is where a lot of mathematical chemistry went wrong,
is people, and I think Wolfram does this in Mathematica, he assumes that chemistry is a reaction
where atom A or molecule A reacts with molecule B to give molecule C.
That's not what chemistry is. Chemistry is take some molecule, take a liquid or a solid, mix it up and heat it.
And then extract it. So the programming language is actually with respect to the process operations. And if you flick in process space,
nod in chemical graph space, you unlock everything
because there's only a finite number of processes
you need to do in chemistry.
And that's reassuring.
And so we're in the middle of it, it's really exciting.
It's not, you know, the deal on the end all,
and there is, like I say, errors that can creep in.
One day we might be able to do it without human interaction, you simulate it and you'll know enough about the simulation that will, you know, I'm the lab won't catch fire.
But there are so many safety issues right now that we've got to really be very careful, you know,
protecting the user, protecting the environment, protecting misuse.
I mean, there's lots to discuss if you want to go down that route because it's very, very interesting. You don't want no other chokes being made or
or explosives being made or or recreational drugs being made. But how do you stop a molecular
biologist making a drug that's going to be important for them looking at their, you know, particular
assay on a bad actor trying to make meth and
fetamine.
I saw how you looked at me when you said bad actor, but that's exactly what I'm going to
do.
I'm trying to get the details of this so I can be first.
Oh, don't worry.
We can protect you from yourself.
Okay.
I'm not sure that's true, but that statement gives me hope. This ultimately excite you about the future or does it terrify you.
So let's, we mentioned that time is fundamental. It seems like you're at the cutting edge of progress
that will have to happen, that will happen, that there's no stopping it.
And as we've been talking about, I see obviously a huge number of exciting possibilities.
So whenever you automate these kinds of things, just the world opens up.
It's like programming itself and the computer, a regular computer, has created innumerable applications.
It made the world better in so many dimensions.
And it created, of course, a lot of negative things that we, for some reason, like to focus on, using that very technology to tweet about it.
But I think it made a much better world, but it created a lot of new dangers.
So maybe you can speak to when you have, when you kind of stand at the end of the road
for building a really solid, reliable, universal computer, what are the possibilities that are
positive, what are the possibilities that are positive? What are the possibilities
that are negative? How can we minimize the chance of the negative?
Yeah, there's a really good question. So there's so many positive things. From drug discovery,
from supply chain stress, for basically enabling chemists to basically build more productive
in the lab, right? Well, this is the computer is not going to replace the chemist. There's going
to be a Moore's Law of Molecules, right? There's going to be so many more molecules.
We can design so many more diseases we can cure. So chemists in the lab as researchers that's
better for science, so they can build a bunch of, like, they could do science that are much more
accelerated pace. So it's not just the development of drugs. It's actually like doing the basic
understanding of the science of drugs. And the personalization, the cost of drugs right now,
we're all living longer, we're all having more and more,
we know more about our genomic development,
we know about our predetermination,
and we might be able to, one dream I've got is like,
imagine, you know, you can work,
your genome assistant tells you you're gonna get cancer
in seven years time, and you have your personal computer that cooks up the right molecule just for you to cure it, right? That's
a really positive idea. The other thing is when drugs, so right now, I think it is absolutely
outrageous that not all of humanity has access to medicine. And I think the computer might
be able to change that fundamentally because it's
we'll disrupt the way things are manufactured. So let's stop thinking about manufacturing
in different factories. Let's say that computers, clinical grade computers or drug grade
computers will be in facilities all around the world and they can make things on demand.
As a function of the cost, you know, maybe people won't be at a four-delay, it's the greatest patent, but maybe they'll be at the next best
thing and we'll basically democratize and make available drugs to everybody
that they need, you know, and you know, there's lots of really interesting things
there. So I think that's going to happen. I think that now let's take the
negative. Before we do that, let's imagine
what happened. It would go back to really tragic accident a few years ago. We're not accident,
an act of murder by that pilot on the, I think it was Eurowings or Swiss wings off. But
what he did is plane took off. He waited to his pilot, went to the toilet. He was a co-pilot. He locked the door and then set the auto pilot above the out.
So he set the altimeter or the descend height to zero.
So the computer just took the plane into the out.
Now, I mean, that was such a tragedy. Obviously, the guy was mentally ill, but it wasn't just a tragedy for him.
It was for all the people on board.
But what if, and I was inspired by this, and by thinking, what can I do to do, to anticipate problems like this in the computer?
Had the software, and I'm sure Boeing and Airbus will be thinking, ah, maybe I can give the computer a bit more situational awareness.
So whenever one tries to drop the height of the plane, and it knows that above the'll just say, oh no, computer says no, we're not letting you do that.
Of course, he would have been out of find another way, maybe fly it until it runs out fuel or something,
but you know, keep anticipating all the large number of trajectories that can go negative,
all those kinds of running into the Alps and try to at least make it easy for the engineers to build systems that are protecting us that.
Yeah, and let's just think, what are in the computer world right now with KIDLs?
Let's just not think about what I'm doing right now. What I'm doing right now is it's completely
open, right? Everyone's going to know KIDLs and be playing with them, making them easier and easier
and easier, but what we're going to start to do, it makes sense to encrypt the KDLs in such a way you,
you'll, let's say you work for a pharmaceutical company and you have a license to make
given molecule. Well, you get issued with a license by the FDA and your local authority and they'll
say, right, your license to do it. Here it is is encrypted and the KDL gets run. So you have a
license for that instance of use, easy to do. Computer science has already solved the problem. So the fact that we all trust online
banking, right? The right now, then we can secure it. I'm 100% sure we can
secure the computer. And because of the way we have a many, you know, it's like
the same mapping problem that you to actually reverse engineer a KDL will be
as hard as reverse engineering
the encryption key, you know brute force it will be cheaper to just actually buy the
regulated medicine. And actually people aren't going to want to then make their own fake pharmaceuticals
because it'll be so cheap to do it. We'll drop the cost of access to drugs. Now what will happen?
Recreational drugs. People start saying well well, I want access to recreational drugs.
Well, it's going to be up to, it's going to accelerate that social discussion
that's happening in the US and Canada and in the UK everywhere, right?
Because cost goes down, access goes up.
Given cannabis, THC, to some people who have got epilepsy,
isn't literally forgiv the term a no-bra brainer because these poor people go from seizures like every day to maybe seizures just once every few months.
That's an interesting idea that tried to minimize the chance that it can get into like the hands of individuals like terrorists or people that want to do harm. Now, with that kind of thing, you're putting a lot of power in the hands of
governments, in the hands of institutions, and so then emerge the kind of natural criticism you
might have of governments that can sometimes use these for ill, use them as weapons of war, not
weapon, not tools of betterment. So, and sometimes not just war against other nations, but war against
its own people, as has been done throughout history.
Well, I'm thinking, so there's another way of doing a decentralized peer-to-peer version
where, and what you have to do, I'm not saying you should adopt a blockchain, but there is a way
of maybe taking IDLs and putting them blockchain.
Here's an idea, let's just say,
the way we do it in my lab right now,
is we go to the literature,
we take a recipe to make a molecule,
convert that to a kind of a IDL,
and diligently make it in the robot and validate it.
We know that, so I would call mining, proof of work,
proof of synthesis, right?
We'll have proof of the synthesis.
Yeah, but this is cool because, yeah, suddenly when you actually synthesize it, you can get
the analytical data, but there's also a fingerprint in there of the impurities that get carried across
because you can never make something 100% pure.
That fingerprint will allow you to secure your KDL.
So what you're doing is encrypt those two things.
So suddenly you can have people out there mining and what you could do perhaps is do the
type of thing that we need to basically look at the way that contact tracing should have
been done in COVID where people are given the information.
So you're just being in contact with someone COVID.
You choose, I'm not telling you to stay at home, you choose, right?
So now if we could imagine a similar thing like, you know, you have got access to these chemicals,
they will have these effects, you choose and publicize it or maybe it's out somewhere. I don't know,
I'm not a policy maker on this and one of my job here is to not just make the technology possible,
but to have as open as a discussion as possible with people to say, hey, can we stop childhood mortality with this technology?
And to those benefits outweigh the one-off where people might use it for terrorism or people might
use it for recreational drugs. Chemify, which is the name of the entity that will make this happen,
I think we have some social responsibilities as an entity to make sure that we're not enabling
people to manufacture personal drugs, weapons that will.
And what we have to do is have a discussion with society with the people invest in this,
where people that are going to pay for this to say, well, do you want to live longer?
And do you want to be healthier?
And are you willing to accept some of the risks?
And I think that's a discussion to have.
So by the way, when you say personal drugs, do you mean the legal ones or do you have a concern of
just putting the manufacturer of any kind of legal drugs in the hands of regular people because
they might like dose matters that might take way too much? I mean, I would say to be honest,
the the chances of computers being well, shouldn't always never. So the fact I can now say this means
it's totally going to come true, right?
I'm going to do it.
I cannot imagine that computers will be
in people's houses anytime soon,
but they might be at the local pharmacy.
Got it.
Right?
And if you've got a drug manufacturing facility
in every town, then you just go and they give you
your prescription and they do it in such a way,
they format it so that you don't have to take 10 pills every day. You get one
manufactured for you that has all the materials you need and the right distribution.
Got it. But you met your recreation drugs and the reason I'm metric is I know people
are going to speak up on this. If the drug is legal, there's to me no reason why you
can't manufacture a manufacture, I mean,
for recreation. I mean, you can do it right now. What do you have against fun Lee?
I have, so I mean, I'm a chemistry professor in the university.
He's an entrepreneur as well. I just think I need to be as responsible as a candidate discussion.
Sure. No, sure, sure. But I know I'm also, let me be the one that says like there's nothing because you have said
recreation or drugs and like terrorism in the same sentence.
Yeah, yeah.
Okay.
I think let's make sure we draw a line that there's real dangers to the world of terrorists,
of bio warfare.
And then there's a little bit of weed.
So I have, I mean, I, I think it's up to the society to,
to tell is governments what it wants was acceptable, right?
And if it becomes, let's say that THCs become, you know, heavily acceptable,
and that you can modify them.
So let's say there's, let's say it's like blood type.
There's a particular type of THC that you tolerate
better than I do.
Then why not have a machine that makes the one you like?
And then why not?
And why not a perfect brownie?
Yeah.
And I think that that's fine.
But we're so far away from that.
I can barely get the thing to work in the lab, right?
And I mean, it's reliability and all this other stuff. But what I think is going to happen in a short
term, it's going to turbocharge molecular discovery, reliability, and that will change
the world. That's super exciting. You have a draft of a paper titled autonomous intelligent
exploration, discovery and optimization of nanomaterials. So we are talking about automating engineering of nanomaterials.
How hard is this problem? And as we continue down this thread of the positives and the worrisome,
what are the things we should be excited about and what are the things we should be terrified about
and how do we minimize the chance of the terrifying consequences.
So in this robot, the robot does all the heavy lifting. So the robot basically isn't in
body AI. I really like AI in a domain-specific way. One of the, as you should say at this
point, there wasn't an attempt in the 60s. Joshua Leddenberg and some really important people
did this that made an AI to try and guess if organic molecules and a mass spectrometer
were alien or not. Yes. And they failed because they didn't have a assembly theory.
And when I, and I, and, no, wait, what does assembly theory give you about alien versus human
life? Well, no, it just, it tells you about unknown, the degree of unknown.
So you can fingerprint stuff.
They weren't looking at, they were trying to basically just look at the corpus of, or
complex organic molecules.
So when I was a bit down about assembly theory, because I couldn't, couldn't convince
referees and couldn't convince computational, um, people interested in, um, computational
complexity, I was really quite depressed about it. And I mean, I've been working with Sarah Walker's team,
and I think she, you know, I think she also invented in 70th theory in some way when we talk about it later, when I found the AI not working for the Dendral project,
I suddenly realized I wasn't totally insane. Coming back to this nano robot, so what it does is
basically a like a computer, but now what it does is it squirts a liquid with gold in it in a test
tube and it adds some reducing agents, there's electrons to make the gold turn into a nano particle.
Now when gold becomes a nano particle,, gets a characteristic color, a plasma.
So it's a bit like if you look at the sheen on the gold wedding ring
or gold bar or something, those are the ways
of conducting electrons basically reflect light.
What we did is we randomly squirt the gold particle
and the reducing agent in and we measure the UV,
we measure the color.
And so what we do is we've got, the robot has a mind.
So it has a mind where in a simulation,
it randomly generates nanoparticles
and the plasma on the color that comes out,
randomly generates imagines in its head.
It then, well, that's the imaginary side of the robot.
In the physical side of the robot,
it's squirt sin, the chemicals, and looks at the color,
and it uses a genetic algorithm, and it'll map a map elite actually on it and it goes around in cycles and refines the color to the objective.
Now we use two different points. We have an exploration and an optimization. They're two different. So the exploration just says just do random stuff and see how many different things you can get.
And when you get different things, try and optimize and make the peak sharper, sharper
sharper.
And what it does after a number of cycles is it physically takes a sample of the optimized
nanomaterial, reset all the round button flasks, cleans them, and puts the seed, physical
seed back in.
And then what this robot is able to do is search a space of 10 to the 23 possible reactions
in just a thousand experiments in three days.
And it makes five generations of nanoparticles,
which get nicer and nicer in terms of shape
and color and definition.
And then at the end, it outputs a cardio code.
The can then be...
Wow, it's doing the search for programs
in the physical space.
Yeah.
So it's doing it kind of reinforcement learning.
Yeah, yeah.
In the physical space,
with the exploration and the optimization
in the physical space.
And that's Kideal will work on any computer
or any qualified hardware.
So now that's it.
That's now that's a general piece of code
they can replicate somewhat maybe perfectly.
Yeah.
It created.
That's amazing.
That's incredible.
But the nanoparticles themselves are dumb.
The robot has all the thinking.
So we don't try and imply any self-replication or try and get the particles to make themselves.
Although it would be cool to try.
So well, there you go.
That those are famous last words for the end of human civilization would be cool to try
So is it possible to create
Molecules to start approaching this question that we started this conversation which which is the origin of life
So to start to create molecules that have
Life-like qualities. So have the replication, have complex,
start to create complex organisms.
So we have done this with the oxides.
I talked about earlier, the limton moxides
and the rings and the bulls.
And the problem is, what they do,
they auto-calytically enhance one another.
So I guess you would call it self-replication.
But because there's limited function and mutation, they're pretty dumb, so they don't do very much.
So I think the prospect of us being able to engineer a nanomaterial life form in a short
term, like I said earlier, my aim is to do this, of course.
I mean, on one hand, I'm saying it's impossible, on the other hand, I'm saying I'm doing it.
So, which is it, Lee? It's like, well, I think we can do it, but only in the robot.
So, the causal chain that's going to allow it is in the robot. These particles, if they do start
to self-replicate, the system's going to be so fragile that I don't think anything dangerous will come out. It doesn't mean we shouldn't treat them as potentially, you know.
I mean, I don't want to scare people like gain a function.
We're going to produce stuff that comes out.
Our number one kill switch is that we always try to search a space of objects that don't exist in our,
it don't exist in the environment.
So even if something got out, it just would die immediately.
It's like making a silicon life form or something.
Which is the opposite of oftentimes gain of function research,
just focused on like, how do you get a dangerous thing
to be closer to something that works with humans?
Yeah, and they'll have a jump to humans.
So that's one good mode to operate on is always
try to operate on chemical entities that are very different than the kind of chemical
environment that humans operate in. Yeah. And also, I mean, I'll say something dramatic,
which may not be, may not be true. So I should be careful. If let's say we did discover a new living system
that it was made out of a shadow biosphere and we just released it in the environment,
who cares? It's going to use different stuff.
It'll just live.
Just live, yeah. I found one of my biggest fantasies is actually his like a planet. This basically can be half in the sun.
It doesn't rotate, right?
And you have two different origins of life on that planet.
And they don't share the same chemistry.
And then the only way time they recognize each other is when they become intelligent,
they go, well, what's that moving?
Yeah.
I want to say the core of all, and that's fascinating.
I mean, so one fascinating thing to do is exactly what you're saying, which is a life
bomb, which is like try to focus on atmospheres or chemical conditions of other planets and
try within this kind of exploration, optimization system, tried to discover life forms that can work in those
conditions and then you send those life forms over there. See what kind of stuff they build up.
Like you can do like a large scale, it's kind of a safe, physical environment to do large scale
experiments. It's another planet. Yeah, so look, I'm going to say something quite contentious. I mean, Elon wants to go to Mars.
I think it's brilliant wants to go to Mars, but I would counter that and say, is Elon just obsessed
with getting humanity off Earth or what about just technology? So if we do technology, so Elon,
either needs to take a computer to Mars, because he needs to manufacture drugs right on demand,
right? Because zero cost payload and all that stuff is just code. All what we do is we actually say hang on, it's quite hard for
humans to survive on Mars. Why don't we write a series of origin life algorithms where we put
our culture in bed, our culture in it, right? It's a very riddly spot from Reethius, right? Yeah,
which is a terrible film by the way, but anyway. And dump it on Mars and just terraform Mars. And what we do is we
evolve life on Mars that is suited to life on Mars, rather than brute forcing human life
on Mars. So one of the questions is, you know, what is human culture? What are the things
you encode? Some of it is knowledge, some of it is information. But the thing that Elon
talks about, the thing I think about, I think
you think about as well, is some of the more unique aspects of human nature, of what makes
us human, which is our particular kind of consciousness. So he talks about the flame
of human consciousness. That's one of the questions. Can we instill consciousness into other beings?
Because that's a sad thought that whatever this thing inside our minds that hopes and dreams
and fears and loves can all die. Yeah, but I think you already know the answer to that question.
I'll die. Yeah, but I think you already know the answer to that question.
I have a robot law at home.
My kids call it CC, called CAR.
It's a robot mode.
And the way it works, it has an electric field around the perimeter.
And it just tell it the area.
And it goes out and goes from its base station, just moves a bit.
Guests of the perimeter detects perimeter and then chooses a random angle, rotates around and goes from its base station, just mose a bit. Guests of the perimeter, detects perimeter, and then chooses a random angle, rotates, random goes on.
Yeah.
But my kids call it cool cutter, it's a she. I don't know why it's a she. They just,
they were like, quite young, they called it, I don't want to be sexist there, it could
be a he, but they liked, they gendered the lawnmower.
They gendered the lawnmower.
Okay.
Yeah. Why not?
But I was thinking this law
mower, if you apply in a great information theory to law
mower, the law mower is conscious.
Now, information, integrate information theory
is that people say it's a flawed way of measuring
consciousness.
But I don't think it is.
I think assembly theory actually
measures consciousness in the same way.
Consciousness is something that is generated over a population
of objects of humans. Consciousness didn't suddenly spring in. Our consciousness is evolved
together, right? The fact we're here and the robots we leave behind, they all have some
of that. So we won't lose it all. Sure, consciousness requires that we have many models being generated
as not just one domain specific AI, right? I think the way it creates consciousness,
I'm gonna say unashainably,
the best way to make a consciousness
is in a chemical system,
because you just have access to many more states.
And the problem right now
we're making silicon consciousness
is you just don't have enough states.
So there are more possible states,
or sorry, there are more possible configurations
possible in your brain,
than there are atoms in the universe. And you can switch between them. You can't
do that on a core i10. It's got 10 billion, 12 billion, 14 billion transistors, but you
can't reconfigure them as dynamically.
Well, you've shared this intuition a few times already that the larger number of states, somehow correlates to greater possibility of life, but it's also possible
that constraints are essential here. Yeah, yeah. I mean, but coming back to the you worry that
something's lost, I agree. But I think that, you know, we will get to an age EI, but I wonder if it's
not, it can't be separate from human, it can't be separate from human, it
can't be separate from human consciousness because the causal chain that produced it
came from humans. So what I kind of try and suggest heavily to people worry about the
existential threat of AI saying, I mean, you put it much more elegantly earlier, like
we should worry about algorithms on dark algorithms written by human beings on Twitter driving us insane, right?
I'm doing acting in odd ways.
Yeah, I think intelligence.
This is what I have been in eloquent in trying to describe it
partially because I try not to think too deeply through this stuff because then you become a philosopher,
I still aspire to actually building a bunch of stuff.
My sense is superintelligence leads to deep integration into human society.
So intelligence is strongly correlated. like intelligence, the way we conceive of intelligence materializes as a thing that becomes a fun
entity to have at a party and with humans. So like it's a mix of wit intelligence, humor, like intelligence, like knowledge,
ability to do reasoning and so on, but also humor,
ability to do reasoning and so on, but also humor, emotional intelligence, ability to love, to dream, to share those dreams, to play the game of human
civilization, to push and pull the whole dance of it, the whole dance of life.
And I think that kind of super intelligent being is not the thing that worries me.
I think that ultimately will enrich life.
It's again, the dumb algorithms, the dumb algorithms that scale in the hands of people
that are too don't study history, that don't study human psychology and human nature,
just applying too broadly for selfish near-term interests.
That's the biggest danger.
Yeah, I think it's not a new danger, right?
Right.
I now know how I should use Twitter
and how I shouldn't use Twitter, right?
I like to provoke people into thinking.
I don't want to provoke people into outrage.
It's not fun, it's not a good thing for humans to do, right?
And I think that when you get people into outrage, they take sides and taking sides is really bad. But I think
that we're all beginning to see this. And I think that actually, I'm very optimistic
about how things will evolve. Because, you know, I wonder how much productivity has
Twitter and social media has taken out humanity, because how many now? I mean, so the good thing about Twitter is it gives power, so it gives voice to minorities,
right? And that's good, in some degree. But I wonder how much voice does it give to all sorts of other
problems that don't need this emerge? By the way, when you say minorities, I think,
problems that don't need this emerge. By the way, when you say minorities, I think,
or at least if I were to agree with you,
what I would say, minorities broadly defined
in these small groups of people that
it magnifies the concerns of the small versus the big.
That is good to some degree.
But I think, I mean, I have to be careful
because I think I have a very,
I mean, I think that the world isn't that broken, right?
I think the world is pretty cool place.
I think academia is really great.
I think climate change presents a really interesting problem
for humanity that we will solve.
Alaka, you said it's a pretty cool problem.
But for civilization, it's a big one.
What is the point?
There's a bunch of really big problems
that have solved significantly improve
the quality of life, all right.
That ultimately is what we're trying to do.
Improve how awesome life is for the maximum number of people.
Yeah, and I think the coming back to consciousness,
I don't think the universe is doomed to heat death, right?
It's one of the optimists, that's why I want to kind of
nudge you into thinking the time is fundamental,
because the time is fundamental, then suddenly,
you don't have to give it back.
The universe just constructs stuff.
And what we see around us in our construction,
I know everyone's worried about how fragile civilization is.
And I mean, look at the fundamentals.
We're good until the sun expands, right?
We've got quite a lot of resource on earth.
We're trying to be quite cooperative.
Humans are nice to each other when they're not under enormous stress.
We're coming back to the consciousness thing.
Are we going to send human beings to Mars or conscious robots to Mars?
Or are we going to send some hybrid?
And I don't know the answer to that question right now.
I guess Elon's going to have a pretty good go at getting there.
I'm not sure whether I have my doubts, but I'm not qualified.
I'm sure people have their doubts that computation works.
But I've got it working. And you know, and
most of the cool technologies we have today, and take for
granted, like the airplane, a foreign mentioned airplane, or
things that people doubted, every like majority of people
doubted before they came to life. And they come to life.
And speaking of hybrid AI and humans, it's fascinating
to think about all the different ways
that hybridization that merger can happen.
I mean, we have currently have the smartphones
so there's already a hybrid,
but there's all kinds of ways that hybrid happens,
how we and other technology play together,
like a computer.
How that changes the fabric
of human civilization is like wide open, who knows, who knows.
If you remove cancer, if you remove major diseases from humanity, there's going to be a bunch
of consequences we're not anticipating. Many of them positive,
but many of them negative, many of them, most of them, at least I hope, are weird and wonderful
and fun in ways that are totally unexpected. And we sitting on a porch with a bottle of
jagged annuals and a rock roll, see kids these. Don't appreciate how hard we had it back in the day. I got to ask you
Speaking of nudging you and Yoshabok
Nudge each other on Twitter quite a bit in a wonderful intellectual debates
And of course for people who don't know Joshua Bach. This is brilliant guy. He's been on the podcast a couple times
You tweeted or he tweeted he tweeted
Joshua Bach everyone should follow him as well. She definitely follow mr. Lee Kronin, dr. Lee Kronin
He tweeted dinner with Lee Kronin. We discussed that while we can translate every working model of existence into a turn machine
The structure of the universe might be given
by wakes of nonexistence in a pattern generated by all possible automata which exist by default.
And then he followed on saying, face to face is the best.
So the dinner was face to face.
What is Joshua talking about in wakes, quote, wakes of non-existence in a pattern generated
by all possible automata which exists by default. So, a tomata exists by default, apparently.
And then there's wakes of non-existence with the hell's non-existence in the universe. That's
with the hell's not existence in the universe. That's a, that's, and also in another conversation,
you tweeted, it's state machines all the way down,
which presumably is the origin story of this,
the next question.
And then, Jersha said, again, nudging, nudging.
Nudging slash trolling.
Jersha said, you've seen the light welcome friend. Many foundational physicists effectively believe
in some form of hyper computation. Lee is coming around to this idea. And then you said,
I think there are notable differences. First, I think the universe does not have to be a computer.
Second, I want to understand how the universe emerges, constructors
that build computers. And third, is that there is something below church touring. Okay. What the heck
is this dinner conversation about? Maybe put another way, maybeing out a little bit, are there interesting agreements,
or disagreements between you and Joshua Bach
that can elucidate some of the other topics
we've been talking about?
Yeah, so Yasha's an incredible mind
and he has, he's so well read
and uses language really elegantly,
bamboozles me at times.
So often I'm using, I'm describing concepts
in a way that I built from the ground up and so we misunderstand each other a lot.
He's floating in the clouds.
Something like, not quite, but I think so. There's concept of a churring machine. So a machines, cheering machines, I would argue. And I think this is not the cheering
machine, the universe is not a cheering machine. Biology is not even a cheering machine, right?
And because cheering machines don't evolve, right? There is this problem that people see
cheering machines everywhere, but isn't interesting. The universe gave rise to biology, that gave
rise to intelligence, that gave rise to Alan Turing, who invented the abstraction of the Turing machine and allowed us to digitize.
And so I've been looking for the mystery at the origin of life, the origin of intelligence
and the origin of this.
And when I discuss with Yasha, I think Yasha, he was saying, well, the universe, of course,
the universe is a Turing machine, of course, there's a hyper computer there.
And I think we got kind of trapped in our words and terms, because of course, it's possible
for a cheering machine or computers to exist in the universe. We have them. But what I'm trying
to understand is, where did the transition of continuous to discrete occur? And I've been,
and this is because of my general foolishness of understanding the continuous.
But I guess what I'm trying to say is there were constructors before there were abstractors.
Because how did the universe abstract itself into existence? And it goes back to earlier saying
could the universe of intelligence have come first? What's the constructor? What's the constructor?
So the abstractor is the ability of, say, of Alan Cheering and Goodall and church
to think about the mathematical universe and to label things
and then from those labels to come up with a set of axioms with those labels
and to basically understand
the universe mathematically and say, okay, I can label things.
Where did the label come from?
Where is the prime labeler?
Even if the universe is not a touring computer, does that negate the possibility that a touring
computer can simulate the universe?
Just because the abstraction was formed at a later time, does that mean that abstraction,
this is to our cellular-atomata conversation.
Yeah.
You were taking away some of the magic from the cellular-atomata because very intelligent
biological systems came up with that cellular-atomata.
Well, this is where the existence is to default, right?
Is it, does the fact that we exist and we can come up with a cheering machine? Does that mean the universe has to be a cheering
machine as well? But can it be a true machine? That's a, there has to be an again a be. Can it be sure?
I don't know, I don't understand if it has to be or not, can it be, but can the universe have
understand if it has to be or not, can it be, but can the universe have cheering machines in it? Sure, they exist now. I'm wondering though, maybe,
and this is really, really hairy, is I think the universe, maybe in the past,
did not have the computational power that it has now. This is almost like a law of physics, so the computational
power is not... You can get some free lunch.
Yeah, I mean, the fact that we now, we sit here in this period in time and we can imagine
all these robots and all these machines, and we built them. And so we can easily imagine going back in time that the universe was capable of having them, but
I didn't think it can. So the universe may have been a lot dumber,
yeah, computationally. And I think that's why I don't want to go back to the time
discussion, but I think it has some relationship with it. The universe is basically smarter now than
it used to be and is going to continue getting smarter over time
because of novelty, generation, and the ability to create objects within objects within objects.
You know, there's perhaps this ground in physics, there's this intuition of conservation,
that stuff is concerned. Like, you're not, you've always had all everything, you you just rearranging books and the bookshelf through time.
So you're saying like new books are being written.
Which laws you want to break? The origin of the big bang, you had to break the second law
because we got order for free. Yeah. Well, what I'm telling you now is that the energy
isn't can preserve in the universe. Oh, it is a second law. Okay, I got you. So because, but not in a mad way.
Okay, so,
computation,
potentially is not conserved,
which is a fascinating idea.
Intelligence is not conserved.
Our complexity is not conserved.
I suppose that's deeply connected to time being fundamental.
The natural consequence of that is if time is fundamental and the universe is inflating
in time, if you like, then there are one or two conservation laws that we need to have
a look at. And I wonder if that means the total energy of the universe is actually increasing over
time.
And this may be completely ludicrous, but we do have all this dark energy that we have
some anomalies, let's say, dark matter and dark energy.
If we don't add them in, galaxies, so dark matter, I think, doesn't hold, you know,
you need to hold the galaxies together and there's some other observational issues
Good dark energy just be time
So figuring out what dark energy is my gillsome
deep clues about this
Not just time but the consequences of time. So it could be that I I mean, I'm not saying there's perpetual motions allowed in this free lunch,
but I'm saying if the universe is intrinsically asymmetric
and it appears to be, and it's generating novelty
and it appears to, couldn't that just be a mechanistically
how reality works?
And therefore, I don't really like this idea that the...
So I want to live in a deterministic universe that is undetermined.
Right? The only way I can do that is that time is fundamental.
Because otherwise, all the rest of us just is just slight of hand.
Because the physicists will say, yes, everything is deterministic.
Newton is Newtonian mechanics, it's deterministic.
Quantum mechanics is deterministic.
Let's take the Everettian view.
And then basically we can just draw out this massive
universe branching, but it closes again, we get it all back.
And don't worry, your feeling of free will is effective.
But what the physicists are actually saying is the entire future is mapped out.
And that is clearly problematical and clearly, is this not so clear?
Yeah, it's just problematic.
Yeah, yeah.
So it's, it's, it's, it's, it's, it's, it's, it's, it's, it's, it's, it's, it's, it's
problematic to you.
Well, creature along the timeline.
I want to reduce the number of beliefs I need to understand the universe.
So if time is fundamental, I don't need to have magic order at the beginning,
and I don't need a second law.
But you do need the magical belief that time is fundamental.
Well, I need the observation that I'm seeing to be just the
cow it is all the way down.
But the earth also looks flat if you agree with your observation.
So we can't necessarily trust our observation.
I know the earth isn't flat because I can send a satellite into space.
No, you see now I'm using the tools, the size, the technology.
But I'm saying I'm going to do experiments that start to show.
I mean, I think that it's worth.
So if you can't, so if I cannot do an experiment or a thought experiment,
that it will test this assumption, then the assumption is without merit really in the end,
you know, that's, it's fine.
Yeah.
So that's a beautiful idea you hold yourself to.
That's, that's, that's given that you think deeply in a philosophical way. You think
about some of these really important issues and you have theoretical frameworks like assembly theory.
It's really nice that you're always grounded with experiment. That's so refreshing. That's so refreshing, that's so beautifully refreshing. Now that we're holding you to the grounded and experiment,
to the harsh truth of reality, let me ask the big ridiculous question,
what is the meaning of this whole thing? What's the meaning of life?
Why? This time is fundamental, it's marching forward,
and along this long timeline, come along a bunch of descendants of
apes that have come up with cellular automata and computers and now computers. Why?
I have so many different answers to this question, it depends on what day. I would say, the given the
way the conversation had today, I would say the meaning, well, we make on what day. I would say the given the conversation I had today,
I would say the meaning, well, we make our own meaning, I think that's fine. But I think
the universe wants to explore every possible configuration that it's allowed us to explore.
And this goes back to the kind of question that you're asking about, yasha and the existence
and non-existence of things, right? So if the universe is a churring machine,
it's churning through a lot of states.
And you think about combinatorial theory
before assembly theory.
So everything is possible.
What Yasha and I were saying is,
well, not everything is potent.
We don't see the combinatorial explosion.
We see something else.
And what we see is evidence of memory. So there's,
there clearly seems to be some interference between the combinatorial explosion of things
and what the universe allows. And it's like this kind of constructive, destructive interference.
So maybe the universe is not just about, it is assembling objects in space and time and those objects
are able to search more space and time and the universe is just infinitely creative. And
I guess I'm searching for why the universe is infinitely creative, it is infinitely creative
and maybe the meaning is just simply to make as many objects, create as many things as possible.
And I see a future of the universe that doesn't result in the heat there for the universe.
The universe is going to extract every ounce of creativity, it can out of it,
because that's what we see in Earth, right?
And if you think that almost like intelligence is not conserved,
that maybe creativity isn't either, maybe like...
it's an infinite well. So like creativity is ultimately
tied to novelty. You're coming up with cool new configurations and things. And maybe
that just can continue. Definitely. And this human species that was created along the
way is probably just one method. Like that's able to ask the universe about itself, it's just one way to explore
creativity.
Maybe there's other meta levels on top of that.
Like obviously as a collective intelligence will create organisms, maybe there'll be organisms
that ask themselves questions about themselves in a deeper, bigger picture way that we humans do.
First to ask questions about the humans and then construct some kind of hybrid systems
that ask themselves about the collective aspect.
Just like some weird stacking that we can't even imagine yet.
And that stacking, I mean, I have discussed this stacking a lot with Sarah Walker, who's
a professor of physics and astrobiology, ASU. And we argue about, you know,
how creative the universe is going to be, and is it as deterministic as all that, because I think
she's more of a free will thinker, and I'm of a less free will thinker, but I think we're
beginning to converge and understanding that. Because there's simply a missing understanding. Right now,
we don't understand how the universe, we don't know what rules the universe has to allow
the universe to contemplate itself. So asking the meaning of it, before we know, even know
what those rules are, is premature, but my guess is that it's not meaningless, and it isn't
just about that. And there are three levels of meanings. Obviously, the universe wants
to do stuff. We're interacting with each other, so we create meaning in our own society and our own
interactions for humanity. But I do think there is something else going on. But because reality
is so weird, we're just scratching at that. And I think that we have to make the experiments
better. And we have to perhaps join across not just for the computation
lists and what I try to do with Yasha is meet him halfway. So what happens if I become
a computation list? What do I gain? A lot, it turns out, because I can make Turing machines
in the universe. Because on the one hand, I'm making computers which are state machines
inspired by Turing. On the other hand, I'm saying they can't exist. Well, clearly, I can't
have my cake and eat it.
So there's something weird going on there.
So then did the universe have to make
a continuous to discrete transition,
or is the universe just discrete?
It's probably just discrete.
So if it's just discrete, then there are,
I will then give Yasha his cheering-like property
in the universe, but maybe there's something else below it,
which is the constructor that constructs a cheering machine that then constructs, you know, is a bit like the, you generate
a computing system that then is able to build an abstraction that then recognizes it can
make a generalizable abstraction because human beings, with mathematics, have been able
to go on and build physical computers, if that makes any sense. And I think
that's the meaning. I think that's, you know, as far as we can, the meaning will be further
elucidated with further experiments.
Well, you mentioned Sarah. I think you and Sarah Walker are just these fascinating human
beings. I'm really fortunate to have the opportunity
being your presence to study your work,
to follow along with your work.
I'm a big fan.
Like I told you offline,
I hope we get a chance to talk again with,
perhaps just the two of us,
but also Sarah, that's a fascinating dynamic
for people who haven't heard.
I suppose on club houses where I heard you guys talk,
but you have an incredible dynamic.
I also can't wait to hear you and Yoshitok.
So I think if there's some point in this predetermined
or yet to be determined future,
where the three of us, UN Sarah or the four of us
with Yoshitok could meet and talk would be a beautiful future. where the three of us, you and Sarah, or the four of us with Yosha,
could meet and talk would be a beautiful future.
And I look forward to most futures,
but I look forward to that one in particular.
Lee, thank you so much for spending your valuable time
with me today.
Thanks, Lex, it's been a pleasure.
Thanks for listening to this conversation with Lee Cronin.
To support this podcast,
please check out our sponsors in the description.
And now, let me leave you with some words from the mad scientist Rick Sanchez of Rick and
Morty fame.
To live is the risk at all.
Otherwise, you're just an inner chunk of randomly assembled molecules drifting wherever
the universe blows you.
Thank you for listening and hope to see you next time.
you