Hello, hello.
But before we get into it a little update, thisologist Dr. Adam Becker has recently released a new book.
It's titled "More Everything Forever." AI overlords, space empires, and silicon valleys crusade to control the fate of humanity. It's about the ideology of technological salvation where this religious belief comes from. Who's pushing it by pretending at science instead of religion and how it's taken over silicon valley? And also, how it threatens to take over the world. Again, his book "More Everything Forever." That's his new one. And he told me by email, "I'm pretty hopeful that we can successfully fight back against this stuff."
So you'll hear more about his book "What Is Real?" but also just an update more everything forever is now out. Okay, onward. Oh, hey, it's your old internet uncle, a deadward bon podcast.
βHere with another episode of "Alleeword High." So do you remember your first real existential crisis?β
Also, if you clicked on this and don't know Jack or shit about quantum physics, you're in the right place. You're in good company. Okay, before we spiral into deep, deep space and dark matter,
let's shine a little light on some business. So first off, thank you to everyone on patreon.com/allegies
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Okay, quantum ontology. So many syllables. What do they mean? Quantum in terms of physics deals with
βmatter and energy at its most fundamental level, and quantum comes from the Latin meaning,β
"How much? How far? How great and extent? Already so many questions just to the definition of this. Also, ontology comes from the root on, meaning "been." And it is the branch of metaphysics dealing with the nature of being. So quantum ontology. Matter, what the hell is it? What do we made of? What is real? Just talk a bit about your brain kiddos because this week's episode is just a hearty. It's a feast of information. It's dense. It's like a bucket of mashed potatoes.
And it's filling, like drinking a pint of gravy. It's going to make you question
everything about life itself. What is reality? What exists? Why are we here? But first,
will we cover everything about this topic? Hell no. Will we have to leave out a bunch? Hell yes. Consider this like a warm welcome and entree into some of the basic concepts about the hiccups
βin observing and understanding existence. So thisologist has a BA in philosophy and in physics fromβ
Cornell and a PhD in astrophysics from the University of Michigan is a celebrated science writer and the author of the new book. What is real? The unfinished quest for the meaning of quantum physics, which, by the way, the Wall Street Journal calls fascinating, the New York Times calls a thorough illuminating exploration of the most consequential controversy raging in modern science. Splendid says the Washington Post science magazine calls it riveting. So the book, it's good.
I met thisologist about four years ago at Sycome Camp and he handed me his business card which read freelance astrophysicist. I was like I like this guy. And then the next year he mentioned he was pitching a book and then the following year he said he had a book deal and was writing it and now here we are. His book recounts a lot of the drama in the quantum physics world. Spoi County is there some not only are you gonna walk away with an exciting overview of what the hell
the universe may be all about but you'll also hear about some academic in fighting and why it's exciting that there are so many mysteries and the universe. So in between seminars and panels at Sycome Camp we pulled up a couch. We got to talk and so a settlement for philosophical physics fun times wherein we discussed what matter is made of and how many universes there could be and why what we think we know just does not add up and how someone could say you're wrong but maybe
you're right or than everyone realizes and also how an inbox can be a lot like a crackpot and how to tackle your dreams when they seem too big to fathom and Einstein and String Theory and gravity and tunneling and wormholes and cats and more with astrophysicist author and quantum ontologist Dr. Adam Becker. Hello, we fun. Yes. Okay, so is this good? Yeah, let me check your levels. Okay, hi. How's this?
It's great.
that I could go back in time to ask you about your childhood? I guess you could. Sure. Why not? Would a wormhole do it or is it a different type of tunnel on time? I mean there's no there's no known way that would definitely work to go back in time but wormholes are one of the you know better theories about how you could maybe do it. Okay. So let's go through a
wormhole. Now going back, did you always like physics, astrophysics? How do you
how does someone decide that they're into something so complex? Wow, that's a good question. So yeah, see, I didn't think that I was going to sit on a couch and talk about my child here. But yeah, you trap me. Yeah, so when I was a really little kid, like a lot of other kids, I wanted to be a paleontologist because dinosaurs are awesome. And then I discovered space and decided no, no space is more awesome. And so I got really into space and astronomy and astrophysics
and then sort of slowly slid from astrophysics just to physics. And so by the time I was in high
βschool, I thought, okay, yeah, I think physics is the direction I want to go in. This seems reallyβ
interesting. And I riddle a lot of pop physics books and they said some confusing things. And in
particular, they talked about two theories that said really wild and strange things about the world. One of them was Einstein's relativity and the other one was quantum physics. And you know, really, really weird things in both of those theories, but turns out relativity doesn't require more than like early high school math. Okay. You don't need calculus, you don't need me pre-calculus, like it's just geometry and algebra. And so I learned relativity in high school
and I thought, oh, all that weird stuff seems a lot less weird now. I bet when I get to college and I learned quantum physics, that's going to seem less weird, too. That is not what happened. Yeah, no, so instead I got to college and I started learning quantum physics and it didn't get better. It got worse. And so I was in this class where the professor was talking about one of the weird things in quantum physics. I don't remember exactly what? It was a long time ago,
but you know, he was saying something about how when you're not looking at things, you can't talk about what's going on, but then when you look things change and I probably ask something like, okay, but what do you mean by looking what does that mean? And we kind of got into it and I don't
βremember exactly how the fight went down, but I just remember that at the end, he said in this likeβ
really hotty, this painful voice, he said, well, if that's the kind of question that you're interested in, then why don't you go to the philosophy department? But but Jocos on him, I'd already gone to the philosophy department. And so I did double major physics in philosophy. Oh, God. A lot of that was trying to wrap my head around, like what the heck is going on in quantum physics because this is, this is a really, it's a really weird area, but it's also supposed to be this really fundamental
theory about the fundamental constituents of the world, right? Like the tiniest things, the things that the things that make us up are made of, right, like subatomic particles, and yet it wasn't at all clear what was going on. And so I started digging into that and the more I dug into it, the weirder got, I just did that more and more and eventually thought, you know, I want to write a book about this because this is just so strange and I don't understand why this isn't
βmore widely known. Am I going to, am I going to feel like I'm on mushrooms?β
I mean, look at the cover of my book, it says, "What is real?" And it's got like wavy rainbow lines.
Yeah, so yeah, the answer is probably yes. Okay. Well, let's go back first and define
what is quantum ontology? Yeah, so quantum, I mean, quantum physics is the physics of the ultra-tiny, except that we think that ultra-tiny things make up the world around us. So although it's the physics of the ultra-tiny, there's also a reason to think it's just the physics of everything. Ontology is the study of what there is, of what stuff is in the world. So quantum ontology is the study of, okay, what does quantum physics tell us is in the world? Or, you know, the title
of my book, right? What is real? And it is not clear what quantum physics tells us about the world. It's just not clear at all, even though it's not a new theory, it's been around for almost 100 years. Okay, well, let's start with a theory relativity, which someone with high school math could understand. Sure. Can you give that to me like a nutshell? Sure. He sounds unsure, but that's okay.
Right, so so here's one way of looking at what the theory of relativity tells...
sort of think from our everyday lives that if I'm standing still, or if I'm in a car going
βat like 20 miles an hour, there are some things that just don't change between those two situations,β
like how fast my watch runs shouldn't change between those two situations, or how far it is between my house and the movie theater down the street, that shouldn't change either. No, it turns out, though, that these things that we think of as not changing between those two situations, so we call those things invariant because they don't vary. The invariants between those two situations are into what we think they are. It turns out that actually the rate that my watch
runs at does change between those two situations and the distance between my apartment and the
movie theater down the street does change. There are things that don't change, but those things are not distances or time, they're a combination of space and time, space time. Okay, is time the fourth dimension? Sure, yeah, in relativity it is. Okay. Yeah. And now quantum. Yes. Theory. Yeah. Oh, oh, you want me to do the same thing for quantum theory. Just in a nutshell. Just let us know what we're working with. Yeah, so quantum theory says that there is something very, very unusual going on
βin the world of the very tiny. Really? Yes. And we don't know what that is. What? How many?β
Now is this allowed about dark matter and it doesn't make sense that there's so much space between
atoms? Holy shit. I just realized writing this that atoms name is Adam. Adam. What is life? Also, real quick, the matter all around you. The stuff that makes up everything you see in touch and smell and lick all that matter in the universe is 5% of what exists. And according to NASA, dark matter is something that we can calculate, but we can't see or detect. And it interacts with gravity, but it doesn't emit or reflect light and it's dark. And it makes up about 27% of the universe.
Something called dark energy makes up 68% of the universe. And we know it's strong and it's getting stronger, but we don't get what it is. So just know, the wisest minds alive don't know shit. And if frustrates them enough to keep getting out of bed every morning just to figure it out. Dark matter, sure. We don't really know what's going on there. We know it's around, but we don't know what it's made of. There is a lot of empty space inside of atoms, but that's not really
what's going on here either. That's not why we don't understand this. What's going on instead is, it is hard to understand the relationship between the mathematics of quantum physics and the world that we live in. Because the math works really well. We can use it to predict and explain all kinds of things. But it also doesn't really look like the world around us. And that's fine, you know, things can be weird. It's a big world. There's plenty of room for weirdness. Oh, you're weird. Thank you.
But it's not, there should be a story even if it's a weird story that quantum physics tells us about the world. And it needs to be a story that makes internal sense even if it's a really really weird story, right? There's a difference between being bizarre and being internally contradictory, right? So what he's saying is that the universe kind of like a huge restaurant tab and a friend's birthday dinner where no one has accounted for tax or tip or their three beverages.
Things just don't add up and everyone is testy about it. The weird thing is that the standard way of answering questions like what does quantum physics tell us about the world around us is to say, shut up, that's a stupid question. There's actually a saying in physics to summarize this attitude shut up and calculate. Oh, boy. Because no, no, no one that that was originally coined by the physicist David Merman as as like a pejorative, like he was describing an attitude that other people
have. Right? He no one actually should say that in earnest, but some people do. And yeah, it's it's completely fucking ridiculous. Well, what are these logic gaps? Like I know that
βit's so bizarre and at least if you could understand the bizarreness, but what is it that's so contradictory?β
Like, what do we think? What don't get? Yeah, so so there's this, there's this thing in quantum physics. This sort of fundamental role that the idea of measurement plays. Say that I wanted to describe. I'm holding a pen. Say I want to describe where this pen is. You know, we're where I'm
Going to find this pen using the physics that we had before quantum physics, ...
Okay, quick aside, Newtonian physics is also called classical mechanics. And it deals with objects
βthat aren't at a tiny, tiny scale and how they move and rest and such. So apples falling on our heads,β
tossing your socks in the hamper from across the room. The inertia that causes you to spill hot tea on your crotch in the car. All of those things exist in space and behave in predictable ways. I can do that with three numbers. I can say, okay, this pen is this height above the ground and it's this far off to the right and it's this far in front of me. That's three numbers. It's all I need. If I want to take all the information I have about where I'm going to find
on a electron or some subatomic particle in quantum physics, it's not going to require three
numbers. It's going to require an infinity of numbers scattered across all of space. And the
set of numbers is called a wave function. Okay. And as the name implies, it kind of waves it undulates smoothly, right? And that that wave emotion is described by this very nice, pretty equation called the Schrodinger equation. And the Schrodinger equation kind of smells like a law physics. Okay. It looks like a good candidate for a fundamental law of physics. And it says that wave functions, you know, they wave. They move smoothly. And they move in a completely determined fashion.
There's nothing random or probabilistic about it. Okay. So when we zoom all the way into an atom or the elements that make up an atom, instead of having three dimensions x, y, z, we have an infinity of numbers to describe its location and those infinity of numbers make up a wave. Got it? Look, we understand everything makes sense. We're pretty much quantum physicists now, all of us. Just kidding, but we can still celebrate it. But the standard way of using quantum physics says,
okay, wave functions obey the Schrodinger equation except when you look, when you actually look for the electron, the Schrodinger equation is temporarily suspended at which point this entire other law of physics that is completely different in contradictory comes and it's called the Born Rule. This is Jason Born. Okay. It's actually named for German mathematician and physicist Max Born, who helped develop quantum mechanics and was nominated for a Nobel Prize by Einstein himself.
But most importantly, Max Born is the grandpa of Greece's Olivia Newton John. When I read that, I had chills, like multiplying. But yeah, the Born Rule measures probability of a particle's position and it came on the quantum scene in 1926. And that says, oh yeah, that way of function that moves smoothly. It stops moving smoothly. It goes to zero everywhere except in the spot where you
found the electron. What? Yeah. And so this leads to a couple of questions. First of all, that's weird.
Yeah. Why does that happen? I don't know. Yeah. Weirdness, though, is fine. The real problem, the contradiction, right? The gap in logic is, okay, we have these two rules. They're not the same rule. When do we apply one and when do we apply the other? Right. Because we need to know that because they're not the same rule. The usual answer is, oh, we use the Schrodinger equation when we're not looking when we're not making a measurement. And we use the Born Rule when we do. The problem
is that the idea of measurement is really, really fucking vague. Yeah. Like, is it when I make a measurement? Does quantum mechanics only apply to me, Adam Becker? Like, that, that, that can't be right. Right. Does it work when a dog looks at a electron? Yeah. Right. Or, or, or, or, you know,
βdo you need to be like better qualifies the, yeah. This is the bananas. It's completely nuts. Andβ
and the other thing is like I said, electrons are the only things that have wave functions. This pen has a wave function. You have a wave function. I have a wave function. The universe has a wave function. You get a wave function. You get a wave function. Quantum ontology. It's like the opera of the physics world. Was the wave function of the universe just waiting for billions and billions of years for someone to come along and and suddenly collapse it and, you know, have the Schrodinger
equation not apply? Like, it's just not clear when one equation applies and one another applies. There are people who would say that I am wrong about that. These are the same people who tell you to shut up and calculate. If you ask them, if you pin them down and try to ask them, okay, fine, hot shot. When you use one and when you use the other, they're going to give you something that's either internally contradictory or that contradicts the idea that quantum physics
is more fundamental than Newton's physics. Okay. Yeah. And now, Oivey, there's a lot going on.
βThere is a lot going on. And so the notion of, do you remember Snuffelabegas fromβ
of Snuffelabegas? Is there a Snuffelabegas rule? It's only there when people who aren't big bird
Aren't looking.
mechanics. I can tell you that right now. Carol Spiny does not have like special quantum power.
Just side note, Carol Spiny is the actor and puppeteer who played big bird until his retirement last year. And also did everyone else know his name and then he also voiced Oscar the Grouch or do astrophysicists just to have large brain buckets full of trivia. Where were we? Yes, okay. So the wave function that describes the place of a tiny particle collapses to a point when it's observed. This is wave function collapse. Does observing something make it exist differently?
Okay. So then what does that mean for us? Like if I am a swim. A wave function until someone looks at me and then I'm not. Yeah. What does that mean for ontology for the science and the study of being? What is anyone? Yeah. It means that there's something we don't understand here. It means that the story is clearly not complete. It means that shutting up and calculating is good,
βpractical advice if you want to, you know, calculate stuff. But it means it can't be the realβ
story about the world. Like they did these good tasks, these questions, because there must be something else going on. So the problem then is, okay, what is that story of the world? And the answer is we have multiple candidates for a possible story of the world and interpretation of quantum physics. There are multiple interpretations running around. There isn't a consensus about which one is the right one. Okay. So when it comes to quantum ontology, are we real? What are we? What is reality?
How does it work? Why don't things add up between points versus waves? And why can't we detect or describe dark matter? Or dark energy? Nobody knows. But there have been scratch paper pads and whiteboards just shock a block filled with theories. Let's hear a few. Give me some of the top ones. Like is multi versus one? Yeah, that's one of them. That's probably the most popular one
βother than, you know, the non-answer of shut-up. That's a stupid question. So the many worlds interpretation,β
which was developed by this Joker named Hugh Everett III in the mid-1950s, while he was a
grad student in physics. He basically got drunk on Sherry one night with a couple of other physicists
and then like basically developed this interpretation in part to like stick it to the guy. He was drunkenly arguing with who's an assistant of this guy, Neil Spore, who's a big famous physicist. Okay. So Hugh Everett, who as a child, wrote a letter to Einstein and got a nice response. And then later in his life, sat in on some Einstein's lectures, ran with his posse. So this Hugh Everett, oh, he loved booze and smoking and quantum theory. And he got his PhD in it in the quantum theory, at least.
And Neil's bore, who by the way, was a big deal, Nobel Prize winning quantum physicists and one of like the folks who proposed the structure of an atom with the electron spinning around it and parts of what became known as the Copenhagen interpretation that a particle exists in every position of the wave function until it's observed. Okay. So Everett, he was gently shmammard and arguing with someone from Neil board's lab about Schrodinger's equation, which tries to find the probability of a particle
at a certain point surfing that wave function when we look at it. Okay. So there are arguing. Everett basically said, look, what if it's just all Schrodinger all the time?
βLike, what if that's the only thing that plays on the quantum physics radio station? It's justβ
100% Schrodinger. What if that other thing, the borne rule never comes in, wave functions never
collapse? What does it mean to be while the wall Schrodinger? That like boxed in by Schrodinger, is a dead cat involved? Well, to explain that, I need to bring in the most famous thought experiment and all of quantum physics Schrodinger's cat. Yes. Right. So Schrodinger came up with this way before Hugh Everett. He came up with his cat in the 1930s to explain why he thought there was a big problem here because Schrodinger and Einstein and a couple of the other founders of quantum
physics were really bothered by this problem. It got a special name later on the measurement problem. They were really, really concerned about this. They thought there was something missing from the theory Schrodinger illustrated this by saying, look, you know, maybe quantum particles are weird. You know, maybe they can perform strange tricks. That wave function describing where you're going to find an electron, it sort of smeared out overall of space. That kind of suggests
that maybe the electron is in multiple places at once until you look. But who's looking? And what counts? Nobody actually knows. Anyway. So he said, imagine that you have a box, a sealed box,
In that box you have a very slightly radioactive, you know, lump of metal.
detector pointed at it. And you have this contraption set up so that when the detector detects
βradiation, it drops a little hammer that smashes a glass vile of cyanide. And there's a cat in thereβ
with this whole thing. So basically, if the lump of metal emits any radiation, the cat will die.
Oh, okay. So you put this all together. You seal the box and you wait like 30 minutes. And at this point, the Schrodinger equation says, okay, look, the chunk of radiation that could be emitted by this metal, it either has or has not been emitted. And so the wave function sort of says, well, it's been emitted and not emitted, which means that the detector has and hasn't been tripped, which means that the glass vile has and has not broken. So the cat in there is, according to the
Schrodinger equation, is sort of part dead and part alive, or both dead and alive. It's in this state called a superposition, which is sort of generally the state that most things are in most of
the time, according to the Schrodinger equation. But according to the usual way of thinking about
quantum physics, this sort of very unsatisfying and incomplete idea that you just shut up and don't think about what it means to measure when you open the box, then the cat is either dead or alive. And somehow opening the box may that happen. And that's ridiculous Schrodinger said, you know, maybe particles can be in one place, or more than one place at a time. But cats are either dead or alive. And if you open the box and find a dead cat, then the minute before you open the box,
the cat was either dead or die. And if you open it and find a living cat, it's not like it was
βnot entirely living before you open the box. Right. All right. So remember our Sherryβ
should hammered fun loving physicist Hugh Everett arguing with the biggest fish in the physics pond
that their Copenhagen interpretation was both Haka Horsesbucky. Everett solved this problem at different way. Okay. Everett said, no, no, it's all Schrodinger all the time. So when you open the box, you know, the cat's both dead and alive before you open the box. And then when you open the box, you get entangled with the stuff in the box. Okay, heads up on this next part. Entanglement sounds like a boundary issue in an unhealthy relationship. But it's actually quantum physics and it's cool
as hell. So Everett said, sure. So what that means is, you know, the box split according to the Schrodinger equation. And then when you open the box, look, you split into two copies. And the reason that you don't see both a living in a dead cat is because you split. And so each copy of you only sees one cat, one of you sees a living cat. And one of you sees a dead cat. But both copies only see one cat. So then every time there is a decision, it splits and splits and splits and splits.
Yeah, it's this entanglement sort of contagious and ends up going through the whole world. And so the whole world eventually splits into the dead cat and the living cat branches and this happens over and over again all the time. And so you end up with this massive collection of universes and multiverse.
βMm-hmm. What if there's three options because not everything's on a binary?β
That's right. Yeah. So then you get three copies or what if what if you left the cat in there for 15 minutes, right? So instead of sort of leaving it in there long enough that you had a 50 50 shot of finding a dead cat, you've probably got a living cat. Okay. Right. Sweet. So then there's two copies, but somehow you're more likely to be the copy that sees the living cat. And this is another part of the problem, right? Because quantum physics famously only gives you answers in terms
of probabilities, most almost all of the time. But the Schrodinger equation isn't a random equation. It's completely determined. So where do the probabilities come from? Well, they come in when you use this other rule, the born rule, born rule to refresh, calculates the probability of measuring or observing a particle at a particular spot on the wave. One way of thinking about this is to say, oh, well, sure, you know that when you open the box, you're going to split, but you don't
know which universe you're going to be in when you open the box. You don't know which branch of the wave function that you're going to be in. And so, you know, this rule is about figuring out the probability that you're going to be in the branch with a living cat or a dead cat. It gets really trippy. Okay. Well, so this is the many worlds theory, which is one of the ways that you could try to explain the inconsistency. What about your own life? Do you think about that when you are
About to make a decision?
multiple copies of me. Well, so part of the reason is that I don't subscribe to the many worlds
βinterpretation. I think it's a reasonable option, but I don't know that it's the right answer. Iβ
don't know what the right answer is. And I don't think I don't think anybody can say for sure that they know what the right answer is here because we don't have a good scientific consensus on this debate. But I mean, in my everyday life, I mean, I don't know. I think I'm a pretty regular guy. It's just two things that way I do. Well, you wouldn't be like, well, I might as well make this risky choice because somewhere there's someone making the lesser risky choice. I'll have the
puffer fish. Yeah, that's not that's definitely not how I approach my life. I do not recommend that anybody do that. Do not try that at home. Okay. Yeah. Does it ever, you're a young guy? Does it ever, does it ever trip you out that like in our lifetime? You may not figure out what's up? Yeah, yeah, I mean, that is frustrating, right? Because like you asked me again, we're on a couch talking
βabout my childhood, but you asked me about, you know, what got me interested in this stuff in theβ
first place, I wanted to know what was going on, right? I wanted to know what was up. This is why I keep
saying, you know, it's fine if our theories are weird. We live in a weird place. There are so many weird things about the world. Have you seen a plat bus? Like, like, have you, have you seen, this is, this is one of my favorite examples of like just a weird thing in physics that is nothing to do with quantum anything. Have you done that demo, like a science museum, where you sit in a, in a spinney chair and you're holding a bicycle wheel and then you flip, you flip it upside
down, all of a sudden you start spinning. Like, that's weird. Yeah. Wheel feels like it's fighting you. What the fuck is going on? Like, there's a good answer there, right? So, like, this is just a strange place and I want to know what's going on in it. So, on the one hand, yeah, it's frustrating that
βwe might not know, but on the other hand, it's kind of amazing that we don't know, right? Like, we,β
we have been doing science. We have been thinking about this stuff for a long time and every time we discover something that we find more interesting questions. And this is a complete cliche and
a lot of the first person to say this, but the idea that that there are such fundamental things
in the world that we do not understand, that we, we don't know why these things happen. We don't know what, what, like, the nature of the world is and we are in it. We are of it, one of the great illusions that being human and especially being human here and now in this culture, like, sort of fosters is this idea that somehow we are separate from the world. We are of the world. We are pieces of the world. This is one of the things that's so frustrating about this idea that
oh, the rules are different when you measure. What's, I'm not special. I'm of the world. Like, I don't, there are not different rules for me than there are for anyone else. I'm a piece of the world. I'm part of the world. So are you. So is everyone, we are all of a part with this strange and wonderful place that we live in. And it is not clear how any of this works. Well, what are some other theories? Okay. So we got multiverses, many worlds. What are some
other leading theories of what the hell's going on? Okay. So another one, and this is really going to piss some people off. If I describe this is a leading theory, but it totally is and they're wrong. There's so much controversy here. There's like, there's so much drama. This is, there's a lot of what drew me to this. Once I realized, like, there's so much weird stuff in this area and this unresolved debate, I started wondering, okay, why is it unresolved? And it turns out a lot of
it has to do with just like debate and interpersonal drama between really interesting people. And then I tried to find a book about it. I couldn't find one. So I wrote one. Again, the title is What is Real? The unfinished quest for the meaning of quantum physics by Dr. Adam Becker, available wherever you get books. It makes a great holiday gift. He did not ask me to say that, but it is legit. A very good book. Another leading theory is this thing. It goes by several
different names, but I like to call it pilot wave theory. It's this idea that when you're, you know, when you're talking about, you know, where is that electron? It isn't a place before you look. And when you look, you find it, but there's a wave that's associated with each particle and these waves sort of guide the motion of those particles. And that wave is associated with that wave
Function that we were talking about before.
in the early 20th century to something really profoundly strange going on was that they found that
βthings that they thought were waves, sometimes acted like particles, and things that they thoughtβ
were particles, sometimes acted like waves. Yeah. So like something that you thought was in one place, suddenly like started rippling outward like a wave, something that you thought propagated like a wave and could ripple out and do all those weird wave things, suddenly was acting like a baseball. Like it just really weird. So this is sort of a puzzle. Like how can particles act like waves and vice versa? What's going on? Why does everything seem to have both a particle and a wave
nature? And the answer in this theory, the pilot wave theory is, oh, that's because there are particles and waves and every particle has a wave associated with it that determines how it moves. And so that sounds really simple and really cool. There are problems, right? There's problems
with everything, right? Otherwise there'd be no controversy. The first issue, though I
hesitate to call it a problem is, remember entanglement when things get, when things interact, they start sharing a wave. So when you have two entangle particles, one particle, say that they're entangled and they go flying off in different directions, one of them is way over here and one of them is way over there, right? Like one of them is in Mississippi and one of them is in Calgary, right? Okay? Then the one in Mississippi, if it moves a little bit, that's going to affect the pilot
wave that guides the particle and Calgary. Oh, instantaneously, immediately it happens faster than the speed of light. So that's weird, especially because, you know, we can prove in the math of the
βtheory that that's what happens, but you can also prove that you can't use it for signaling.β
You can't send messages faster than the speed of light this way. Okay? So somehow there's this
subtle connection that we don't see direct evidence of. When I said we don't see direct evidence, we do see evidence. But it's it's indirect evidence. It's evidence that they are connected. You can't, you can't use that connection, you know? Like no one would dispute that they were connected if you could use one to instantly make the other one, you know, send a message. Mm-hmm. But that's not how this works. So in the pilot wave theory, there's not a wave
for a particle. There's a wave that the particle is kind of surfing and it can affect the particles in numerous super positions. But it would be faster than light, which really irks some people because all albi Einstein's relativity says nothing is faster than light. So he didn't like that.
βAlso Adam says this was developed. Basically, I was developed by one of the founders ofβ
quantum mechanics a guy named Louis DeBroy in the late 1920s. But then he was convinced by some other physicists that it couldn't be right. He dropped it was independently rediscovered by another physicist David Bowen in the early 1950s. And he sort of fixed up the problems that were with it that DeBroy had sort of left and and like sort of made it a fully fledged theory and published it. And then he his life like just sending it into a living nightmare for mostly unrelated reasons.
Like yeah, he got caught up in the red scare in the 1950s. Yeah, he got he got blacklisted. He ended up being effectively exiled to Brazil. And then the U.S. government confiscated his passport. So he's trapped in Brazil. Like there's a hole. It's like a movie. It's like a frigging spy thriller. Like, um, like dude got the fucking short end of the stick. Okay. Whoa, now this guy's life. My word. He had his own work at Berkeley confiscated and then classified. So he didn't have access to it.
So that it could be used on the Manhattan Project. And he eventually in his 70s had to have electroconvulsive therapy for depression and just the saga and the drama of his life and political affiliations affected the reception of his work sadly. Okay. But one hiccup is that the particle surfing a pilot wave doesn't work with other theories. Like the relativistic quantum field theory that explains what happens when you smash particles together in a nearly 17 mile particle accelerator
tube underground, which as discussed in the cosmology episode with Dr. Katie Mac is not called the hard on collider. No one has found a way to unequivocally take that theory and reframe it in terms of this pilot wave stuff. That doesn't mean it's wrong. It just means that if it's right, the job isn't finished. But there are a lot of physicists who don't like this stuff for that reason. And because it's got this weird tangled history. So yeah. So that's another option is this pilot
wave theory. There are lots of other options. How often do you think people get stoned and come up with their own theories and email physicists? Well, I can tell you that that happens a lot because
I get a lot of those emails.
that there could be like an interesting psychology paper done here. Oh man, I'm going to get some hate mail for this. That like being an old retired white male engineer must have some effect on the brain that is similar to cannabis or alcohol or something. Because those people, I'm pretty sure they're sober and they send me all sorts of wacky stuff all the time and it's not correct. Do you have a favorite? Oh my god. Any simulation theories? Yeah, I definitely get those. I also
get you know Einstein was wrong and complete fraud and here's why and I'm the only one who found it. And I'm like Galileo. I've been persecuted, right? There's this, there's this thing called the
crackpot index online, which basically you assign more and more points to a crackpot email depending
on like what kinds of claimants they hate. Okay, side note, this crackpot index is indeed a real thing and it was published in 1998 by mathematical physicist John Bias and one score is determined by points with interactions being five points for each word in all caps. Ten points for mailing your theory to someone you don't know personally and asking them not to tell anyone else about it for fear that your ideas will be stolen. Ten points for each statement along the lines of,
I'm not good at math, but my theory is conceptually right so all I need is for someone to just express it in terms of equations. Ten points for each comparison of yourself to Einstein, 20 points for emailing to complain about the crackpot index, 20 points for suggesting that you deserve a Nobel Prize. 30 points for claiming that your theories were developed by an extra
βterrestrial civilization and and I think the worst thing on that index that you can do is compareβ
yourself to go a little. In that vein, either we're going to create simulations that are ingesting for a from reality or civilization will cease to exist. Those are the two options. I don't know what about a simulation. Okay, what if the reason why we cannot reconcile the wave versus the particle and the born versus the Schrodinger? What if that is because it's all fake? Right. So, so couple of things there. First of all, you'd still need to have rules. Like if it's
a simulation in a computer like in a computer we know, there's still rules that the simulation runs on, right? So, and that means that there still has to be some internal logical coherence, right? It can't contradict itself even if it's weird. So there's that. But more importantly,
βand I don't know, I don't know if you're going to like this answer. I think that the simulationβ
thing is kind of not kind of not an economist towards simulation thing is fucking bullshit. Okay.
Hey, it's fucking bullshit and here's what? And this is going to take like a sharp left turn.
It assumes that that's something that it assumes that that's a thing that you can do, which we still don't know that you can do that. And it also assumes that and I guess what I'm really talking about here is this argument that we almost definitely live in a simulation, right? Like, there are those people who say, no, no, we definitely live in one like almost certainly there's almost no chance that this is like the base reality, whatever that means. I really think that's wrong
because it assumes that technology, it assumes a lot about the future progression of technology, but it also assumes that technology always progresses through like the same inevitable stages. It assumes a lot about history and culture and the nature of life and intelligent life and
βintelligence itself. And I think that basically all of those assumptions that go into that argumentβ
that fuel that argument are hopelessly myopic. They're just like completely blinkered and narrow-minded about like the wide variety of ways that things in the world can be and that, you know, technology and civilization and culture can be. Even in this world here and now, like it's a very, it's a very Western centric, male centric, white centric, rich centric argument that, you know,
basically, yeah, no, the inevitable progression of any intelligent being in any logically possible
universe is basically going to be like a rich white dude born between 1970 and 1990. Like, and that's some fucking bullshit. Yeah, that is bullshit. Yeah. So, and also, I've been using maybe everything's assimilation as an excuse for why things are bad, but I shouldn't do that, right? Yeah, I think I think like two things. First of all, you shouldn't do that. Okay, so yes, clearly we can't
Look at global warming and agonizing political situations and forest burning ...
farted in ninth grade history class and people having cancer and being driven from their homelands
βbecause of greed, just as a video game gone wrong and that we should give up and fold our handsβ
in our laps and just wait for the apocalypse or the game over screen. Second, even if this
is a simulation, the suffering is real. Yes. I am suffering. You are suffering. We got to fix that shit. Yeah. A lot of people out there, real suffering. Yeah. We can't just shrug it off as it's all a video game. Yeah, exactly. Do you think that we're real? I mean, yeah, I mean, I guess it depends on what you mean by real, but for any like good meaning of that word, sure, we're real. Yeah, I mean, say that the say that it is assimilation, say that everything I said was wrong,
say that there's some other universe with other laws of physics and other beings and for whatever reason they decided to build this simulation, like to build a computer and inside that computer, like there's a simulation going on and we're in there. We're real. We're in that simulation, in that scenario. Like, there are real entities in that simulation that are you and me and all the things around us, even if that's not how the programmers think about it. Like, I am having experiences
here in this simulation and I have a hand over here and I'm waving it around and I'm banging it on the edge of the sofa. Like, that's all happening. Does the actual structure of the world that it's most fundamental level look anything like the way we think it looks? Probably not, whether or not
βwe're in a simulation, I think that's wrong. Okay. But does that mean that we're not real,β
absolutely not. Okay, so here's a thing. I think everyone, I hope everyone can agree that temperature is a real thing. Like things have temperatures. You know, I can take my my cool nerdy infrared thermometer and point it at the wall and it will tell me that the wall is 74.6 degrees Fahrenheit because we live in a country that doesn't know how to measure temperature. But the thing is
temperature, according to our best understanding of temperature in physics, it comes out of third
dynamics, which is itself something that comes out of statistical physics are really, really interesting field of physics. Temperature is an emergent property. It's not a property that individual subatomic particles can have. It's something that only aggregate collections of stuff have. So one molecule can't have a temperature, but a group of them can because they're all moving
βaround. So Adam, like, is temperature to existence and asking the question, are we real?β
These things in this world around us can emerge out of that lower level, in the same way that temperature is a property that emerges out of the lower level, you know, little jossilings of tiny things because that's where temperature comes from. It's, you know, a tiny object, a tiny piece of that wall is moving around a little bit and all that jiggling together comes out and looks to us like temperature. That's a real thing. That wall is actually a temperature. And we are here.
We are having this conversation even if, you know, the perception that varies such a thing as space and time is something that emerges out of some lower level of reality, there's still a space and a time that we're in, even if it's not fundamental. All right. You've not let me get off the hook about existing. And I still have to like do all my bullshit and get through right to do list like I can't. Okay. Can I ask you a question? Yeah. Yeah. Let's do it. Are you ready? I mean,
I'm, I'm never going to be completely ready. Right for the weirdness that is Patreon. Yeah.
Hi, Patreon. That's the right answer. But before we get to your genius and weird and dry and perfect questions submitted on Patreon, each episode, we donate to a charity of the ologist's choosing. This week, Dr. Becker chose tech bridge girls, which excites, educates and equips girls from low income communities by delivering high-quality STEM programming that empowers a girl to achieve economic mobility and better life chances. And tech bridge
girls was one of the earliest organizations to focus on introducing girls and marginalized communities to the STEM fields. And it's based in Oakland, California, where Adam lives. So that's tech bridgegirls.org. That donation was made possible by sponsors of the show. And so you may hear some words about them right now. Okay. Back to your questions. Travis Demelo wants to know, how does quantum stuff relate to nature? What is its role beyond technology? Oh, I mean,
that's a great question. Quantum physics explains a huge variety of natural phenomena. Like without quantum physics, we wouldn't understand why the sun shines. We wouldn't understand
How our eyes can see that the sun shines.
general way possible, the phenomenon of solidness. Like we wouldn't understand not only why I'm
not passing through this couch right now, but why my bones are solid at all in the first place.
For more on that topic, you can see the osteology episode about bones, just saying. Quantum physics is necessary for understanding where the periodic table of the elements comes from and the idea of molecular structure. So all of chemistry and thus all of biochemistry and thus all of life.
βSo quantum physics explains, you know, or has a really important role in explaining,β
almost every single possible natural phenomenon. So it's important. Yeah, just a little. Well, so a bunch of folks asked about existence and what it really means and why such as
Wendy Lockhart, Sarah Piet, Matthew Thomas Hill and Sam Gordon, who wants to know, how do you deal
knowing what you know about existence and Christy Stewart wants to know, why does it matter if we exist or not? Humans are curious. If we're going to try to engage in the dangerous game of coming up with fundamental human behaviors that are true across cultures, I do think that curiosity is a really good candidate for one. And also more generally, and this is me stealing from my book. So the ideas that we get from science, the picture of the world that comes with our best scientific
βtheories, it filters out into the wider culture. Science is not a separate human activity from theβ
rest of the human world. It is of a peace with the rest of human activity with art and politics and music and, you know, the social sciences and the physical sciences and biological sciences, these all form a unified whole. And so the pictures of the world that come from science not only go out into the other sciences, but out into the wider world, like a really, really simple and fast-ahead and total white dude example, if pernicus and company had not unsenthered
the earth and shown us that know the earth is not at the center of the universe. It seems hard to imagine that Charles Darwin or Chuck E. D. to his friends and company would have had the audacity to suggest that humans are not at the center of biological creation, right? And instead that were just another ape, just another organism in a giant tree of organisms. And without both of those
changes in the way that we think about the world, I mean, first of all you can probably come up with
your own examples here, but without both of those changes, Stanley Kubrick wouldn't have been able to film 2001, right? All those apes at the beginning and, you know, like, come on, that wouldn't happen. And there's lots of other art and culture and just the important things that have happened because of our scientific theories and vice versa. Yeah. Samuel Ball wants to know,
βhas the impossible issue of tunneling been solved yet? Or are there any good theories out there?β
And he's tunneling. What is tunneling? So tunneling, so the short answer is in classical physics, if I put my hand on this table and leave it here, then it will just sort of stay on top of this table, but in quantum physics there's a small chance that my handle suddenly passed through the table. But it's phenomenally unlikely because my hand is quite large and the probability of that kind of tunneling has to do with, among other things, the size of the object
involved for tiny objects tunneling happens all the time. In fact, if tunneling didn't happen, the Sun would not shine. So we know that tunneling happens, tunneling is not more strange than the rest or unexplained than the rest of quantum physics. So if you can get a good picture of the world that comes with quantum physics, you get tunneling for free. Oh, I didn't know what tunneling wasn't told right now. I thought it was maybe something that college kids did at parties. It does
kind of sound like that. This next question about something that we keep in our pants, pocket was asked by patrons Julie Barre, Will Matt Lack, Jess, CJ Stewart Hodges, Mike Ratch, Courtney Markham, Ewan Monroe, Michael Preston, who wanted to know why we should give it rats leftier about the topic, Philip Wayrie, and Spencer wants to know, no matter how much I research, I don't understand quantum computing. Is there an easy way to understand it? Also,
Will quantum computers replace all computers eventually? Like our phones are just super computers.
Yeah, so I'm going to take the second part first.
works seriously in that field thinks that quantum computers will ultimately replace all computers.
βOkay. I don't even think that they're going to replace all super computers. There are thingsβ
that classical, normal computers can do better than quantum computers and vice versa. Okay. And I don't think that that's going to change. Also, let's explain what a quantum computer is. Quantum computer is a computer that harnesses some of the strange and, no, that's not a good way of saying it, right? Because the usual way that people say it is, oh, quantum computers are computer that runs in quantum physics. Everything runs in quantum physics. So all computers run on quantum
physics. Then people say, oh, quantum computer is a computer that uses, you know, special properties of quantum physics to do, you know, certain computational tricks. That's not specific enough either because semi-conductors, which are what, like, the computer and your lab are, and in my
pocket, like, all computers are built on, basically, semi-conducting itself is a quantum property.
Like, you can explain, you can't explain that without quantum physics. A better definition of a quantum computer is a computer that uses specific quantum properties like superposition and entanglement to perform certain computations that normal conventional computers cannot perform as quickly in that way. So it's using the superposition of, say, positive negative here there as kind of a replacement for the binary ones, zero, zero, one, zero. Yeah. And so it can go much faster because it's in an
elemental level. Sort of. I mean, it can do some things more quickly. Basically, instead of having a bit, that's either one or zero, you can have it in a superposition. Okay. And then you can take advantage of some of the wave properties of matter to give you a speed up for certain kinds of computational algorithms. The more specific you get about this, the more wonky and less cool it sounds. Okay. It is. I assure you very cool. Okay. Also, if you've been seeing the words
quantum supremacy lately, thank Google. So in late 2019, just a few weeks ago, Google announced that their quantum computer, which looks to be about the size of a small chandelier that dangles in a cryo chamber colder than outer space is named Sikomor. Well, the processor at small chip is Sikomor, but it needs all those kind of sparkly golden wires to function. Anyway, a team out of university of California Santa Barbara's labs just published a paper revealing that
Sikomor had solved a math problem in 200 seconds. So when it goes, Sikomor, who cares? Well, a lot of people because that same math problem would be pooped by an existing super computer would take years to solve. How many years do you wonder? 10,000 years. So what would take a super computer? 10,000 years to calculate? Sikomor did it in 200 seconds, like three and a half minutes, so quantum computing. It might save us in my kill us either way, get hype. But so you don't think
that it's going to replace all super computers. I don't think anyone's serious in the field thinks that. I mean, there are people who know a lot more about quantum computers than I do. My book is, I mentioned quantum computing. I talked about it briefly. It's not primarily about that.
βI do touch on it because it's important. But I have talked with a lot of people who work in thatβ
field. I don't think anyone thinks that. So I almost, everyone's wrong. I don't think that's going to happen. Okay. Jennifer Quill wants to know, a therapist wants to adjuster to me that one day a physicist will prove the existence of God thoughts. Get a new therapist. Fire your friggin therapist. She is she on mushrooms. Yes, no. This is a safe space. You can tell us if you think her therapist is on mushrooms. Yeah, I know. Okay. That's going to be a no from you dog. Yeah. Got it.
Okay. All Uncle Dad work here. Poppin into say, everyone is entitled to their own spiritual beliefs, just so long as it's not a pressing or screwing up other people's lives. But if you're wondering if scientists tend to be atheists at a higher rate than the general public, that's a yes. Rice University Sociologist Dr. Elaine Howard Ockland had the same question and in her 2010 paper, science versus religion. What scientists really think? She crunched the numbers. So only 2%
of the general US population says, I don't believe in God. But over a third of what she describes as
elite scientists are atheists. But Auckland continues 22% of the scientists who identify themselves
βis spiritual. Also describe themselves is atheists. So wait, what is this spiritual atheist?β
Dr. Ockland interviewed of one biologist who described spirituality this way. Said, "That feeling you get by the sea shore looking over the endless expanse of water,
Or the feeling you get considering the age of all things in existence and how...
sort of an awe at the totality of things. If that's what spirituality is, then I get it." Said the biologist. So, while the narrative of what's controlling our existence, is it a sentient shadow we figure in a cloud watching over us, getting pissed when we lie, or
βis it chaos mixed with chance mixed with logic and a heavy proportion of mystery?β
Those sources may change. They might be different for each individual. But in the end, perhaps what matters most is the awe that keeps you inspired. And the respect that you show to the fellow lumps of molecules with whom you share the universe. Or maybe it's all a video game. Are we real? Probably. But nobody knows. And that is why quantum ontology is cool. Favorite uncertainty principle, Joe? Yes. Hi, you again. So the uncertainty principle was
drafted by German physicist Werner Heisenberg. And yes, Breaking Bad's Walter White took his alter-ego name after this very renowned physicist, who Adam explains in his book, "Had a deep loyalty to Germany?" And was the head of its World War II nuclear program? Gross. Anyway, the uncertainty principle theorizes that when it comes to a particle, its momentum and location cannot be known at the same time. And Adam remains on the spot for a good uncertainty principle,
Joe, per list and urgently bear. Julie Bear wants to know, "Favorite uncertainty principle, Joe." Yeah, I mean, God, they're all just flying out of my head right now, except for the most boring one. The most boring one is, this is, yeah, I apologize to physicist who are listening, you've all heard this before. And probably the person who asked this, cop, pulls Heisenberg over for speeding and says, "Sir, do you know how fast you were going?" And he says, "No, but I know
exactly where I am." Amazing. Yeah. Isabel B. Hopper wants to know which movie or TV show gets
the best. Woo. Like, just quantum. Yeah. Which movie or TV show gets it best. How does quantum leap do? Oh, man, quantum leap. Yeah, quantum leap is almost nothing to do with quantum physics, but I watch that show so much growing up. Good one. Yeah, it was good.
βWhat about what the leap do we know, Julie, Hopper wants to know?β
Our people are affecting the world of reality that they see. Meet back to the R, which is reality. What is reality? If you ever thought about what thoughts are made up, it is so mysterious that can't explain it. Oh, really? What the leap do we know is, um, okay, so take it out of what computer you've got it and put it on like a thumb drive that you don't care about,
set it on fire, bury it. What the blue to we know is wrong about everything and the people who made it are malicious. They trick a friend of mine who is in that movie. They tricked him into participating in the main misleadingly edited his contributions to make it sound like he supported their crazy stuff and also they are literally occult. Oh, no, okay. So you
heard it here first. Okay. This next one is about string theory and as patron Nick Rinders
inquires, string theory, come on. What the fuck? That's an excellent question. I will attempt to summarize it in the smallest junkiest nutshell. Again, string theory is that particles are actually teeny tiny tiny strings, which means that there could be more dimensions and also string theory may unify Einstein's theory of relativity about gravity with the other quantum physics that just do not comply in his book Adam writes quote, string theory doesn't describe a single universe,
but instead describes a string landscape, a phenomenally huge number of possible universes,
β10 to the 500th power or more quote. So what is happening in all those universes? Is my dog there?β
Am I still wearing this yellow sweater? And does string theory finally reconcile the other theories that
don't mesh together? Is string theory the dongle that all of science is waiting for? Kitty Helverson also asked about it as did. Graham Teter saw wants to know string theory, flimflam or science. Sure seems like science. Okay. Yeah. I manage a wants to know does quantum physics have anything to do with our consciousness? Yeah. Because it has something to do with everything. Yeah. So so so yeah on the one hand, sure. Right. So it was a sort of put in my cards
on the table. I see no reason to think that consciousness is not something that arises purely
Out of the behavior of neurons in our brain.
I don't know, neurons are made of subatomic particles, those subatomic particles are governed by quantum physics. So in one sense, yes. But there's often another sense that people have in mind when they ask this question. Okay. Real quick. Remember Schrodinger's cat. So if you
βobserve or measure it, it flips to one position. You know, or oh no. But what's measurement, right?β
What counts as measurement? Some people will say things like, well, maybe consciousness, counts as measurement. Maybe it's when a conscious being interacts with a thing. Maybe that's what measurement isn't quantum physics. A couple of things. First of all, that still leaves you with this problem of okay, but does that mean that like the wave function of the universe was waiting for a conscious being to come along. Also, what is conscious? What do you mean by consciousness?
What counts as conscious? You still have that problem. Yeah. I really seems like a very
human centric view. And I am always really wary of human centric views. There is a mystery
in human consciousness, right? Or there seems to be one. Like, you know, what is human consciousness? Where does it come from? Sure, you can have different views on on how consciousness works. And what it is and like there's their whether or not there's even a mystery there. But I do not see a compelling reason to invoke consciousness and quantum physics given that they're all turnatives. And I do not see why we would say that it is more related to quantum physics than to any other,
you know, issues and physics. Like, I don't think that consciousness plays a more special role in quantum physics than it does in any other area of physics. The question of consciousness, sure, whatever. That's a good question. We can have interesting conversations about it, but I don't see it as related to these questions about quantum physics. Katherine W asked Adam, what is an average day of your life look like? So as an author, he took me
through his process of writing the book, which is so, so, so helpful, no matter what you're working on. And earlier off my key, it mentioned that he has ADHD. You can see the molecular neurobiology episode with Dr. Crystal Doerth, where we touch on that. And so these are his secret tips on how he accomplished these huge goals. This is earnestly life-changing. I love this. What was the process of writing the book like? So first he was object terror after I got the contract to be because I,
you know, like after I finished partying, right? I was, I realized I was on the hook for 90,000
words. And I never published anything longer than about 3000. So that was completely fucking terrifying.
I had a history earlier on in my career of having difficulty getting work done and getting it done on time or getting it finished. And I had by that point, you know, moved past that. I had finished my degree and whatnot, but I still had this mental image of myself as someone who had difficulty
βgetting work done on time. And so it was really extra scared. But I decided, okay, the only wayβ
that I'm going to get through this is if I plan it and then just only pay attention to whatever's in front of me because I can't write 90,000 words, but I can write 600 words a day. And if I do that for a while, eventually I'll have 90,000. So yeah, so I outlined it and I went over the outline with my publisher and they liked the outline. Of course, it changed, right? No plans to write contact with the editor. So for each chapter, I'd outline the chapter. And then I just sort of
work through the outline and write a really shitty first draft and try to do 600 words a day.
And what I do is I would do 50 minutes on in 10 minutes off. And in the 10 minutes off, I wouldn't look at anything with a screen. And I wouldn't read any nonfiction. I would I read exclusively novels and that really helped my brain work. Because I found that if I didn't read it all, I couldn't write. Because if there's nothing going in, nothing's going to come out. Right. So I would write 600 words a day and then get this shitty first draft on and then walk away
from it and then come back and clean it up and fill in all of the blank spots where I had, you know, where I knew I had a quote, but I had to find the quote and stuff like that. And things were changed. And then eventually I'd have a chapter draft that I wasn't embarrassed about and I sent it to my editor and move on to the next one. It was terrifying. There was a lot of research involved. There was a lot of running around and interviewing people, like a lot of people. If you
look in the references there, the very beginning of the references of the book has the list of
βinterviews I conducted. I think it's like 42 interviews or something like that, most of whichβ
were in person. Isn't 42 though the answer to the universe? It is. I don't know if it's actually
42.
in the interview. Anotherologist had stopped into record. I'm going to make you wait to find out who
it was. But we counted his list of interviews in the back of his book and it was like, I love the Hitchhiker's guy, it's artsy. It's 42. Yeah. So yes, it was indeed 42 interviews. The answer to the ultimate question of life, the universe and everything is 42. Yeah. For more on why you can see the Hitchhiker's guy to Galaxy by Douglas Adams. Oh my god, Adams. Again, Adams, is anything fucking real? But yes, Adam Becker says,
don't be afraid to start something. Start writing, just jump in, shitty drafts or your BFF.
βYeah, shitty drafts are really important. I also had, I had like a spare part spinβ
where if I had like one of my, one of my darling's that I couldn't kill like a sentence that I didn't want to get rid of, but it didn't fit. I put it in there and tell myself, like I've lied
to myself and tell myself that I come back and never came back. But more generally, I spent a
lot of time thinking about narrative structure. Like my overall approach was this is a book about really abstract ideas. People care about ideas, but they generally care more about people than they care about ideas and I wanted to make it compelling. I wanted to see if I could write a book about some of the most abstract and strange ideas in physics or in all of science that was difficult to put down. And so I thought, okay, the way to do that is to wrap these ideas up in
βpeople and stories about people. So then it was a question of, okay, how do I build a narrative arcβ
that that will give me good excuses along the way to explain me ideas and introduce the new
characters that are going to come into the story. And that was a real learning process for me.
And I spent a lot of time watching YouTube videos about film editing to learn, like what narrative structure looked like in other forms of stories. Also, Adam stuck to another edict to make a book about quantum ontology accessible. Oh, and no math. That was a rule. Oh, no math and the book. No math. No math. There was there was one equation in the book and I didn't want to have any math in the book. So I wrote it out in words. The equation was two times three equals three times two.
That's it. And that's it. Yes. And what's the shittiest thing about quantum ontology? Is it answering those maybe religious questions or two philosophical or or two loaded questions or what's the shittiest thing? The shittiest thing is definitely dealing with physicists who think that this was all resolved 90 years ago and we should just shut up and calculate. There are so many of them. They are wrong. There are so many good arguments
about why they're wrong and why these questions are interesting. And they're still out there. And and it's just kind of astonishing. But it is getting better and I really think that, you know, as as like a new generation comes into physics, we will see more and more acceptance of these
βquestions as legitimate areas of scientific inquiry. No, what's the best thing aboutβ
quantum ontology? What do you love the most about it? You get to ask the biggest questions. Right? Like these are the biggest questions. Oh, I thought you meant me right now. Oh, no, well, you totally do. That's the best part about your job. The best part about thinking about quantum ontology is you get to ask questions like what is real? Like what's going on? Another Marvin Gaye songs. You get to ask these really deep questions about the world. You get to
think about these wonderful things. And so like chemists have really good demos, right? They get to blow things up and you know put one liquid into another liquid and suddenly it's foaming everywhere and stuff like that. And because for some reason, John, you're a 42-year-old man who meets his attention sustained with tricks. Here's some fucking mentos in the bottom of the diet court. And like biology, you get like creepy crawly things and like cute baby chickens and things like that,
like there's all sorts of fun stuff. Physics doesn't have, you know, cute baby chicks. I mean, you can have cool explosions, but like chemistry really is really, really sweet for that kind of thing. But physics does have the truly, you know, pervasive on its side, right? Like if you want me to talk about some of these questions in the foundations of quantum physics, I can point to literally
Any object and say, look, let's talk about the constituents of that object.
that chair is solid. Let's talk about why this ring on my finger is yellowish instead of silvery,
βright? All of these things come back to quantum physics and thus ultimately to foundations of quantumβ
physics. And it's just amazing. Like it goes after a lot of the reasons why I wanted to go into
science in the first place. So it's everything in its everywhere and we don't understand it. Yeah, it's what it goes to. Yeah, absolutely. Yeah. Well, thank you. I'm more confused about my existence. Good. That means I did my job. Okay. There's a question mark at the end of the title on my book, right? Oh, thank you so much for doing this. Absolutely. This is so much fun. Thank you for doing this with me. You're my favorite quantum ontologist. Oh, thank you.
So remember, ask smart people, the big questions, even if it's about the little stuff because
how else in the world would you discover that there was another you eating puffer fish and cutting banks and texting your crush. Also, if you're jealous of that person, then go do those things yourself, except maybe the poisonous puzzle. That means fish. Whatever. So more links are up in the show notes and up at alleywear.com/allegies/quantamontology. And you can get merch through that site or at allegiesmerch.com. And be sure to follow Dr. Adam Becker on Blue Sky at Adam Becker
βand on Instagram at freelance Astro. And once again, get his book, what is real or his new one?β
More, everything forever about AI overlords. And for shorter kid-friendly episodes, we have
smallities. They're in their own feed. Wherever you get podcasts, you can tell your friends or students. Also, updates, editors, thank you, Jake Chafey and Mercedes-Metland of Maintland audio. For working on this updated one as well as Susan Hale, who is our managing director and of course Newell Tellworth is our scheduling producer. And Aaron Talbert, for adminding the wonderful Facebook group and to Jared Sleeper of Mind Jam Media for Assistant Editing. And of course, to the wizard of
awe, Stephen Ray Morris, who edits all these pieces together and also hosts the Kitty Pod, the Perkast, and the Dino Centric, Sieger Essigrite. And the theme song was written by Nick Thorburn of the Band Islands. Thank you also to Emily White and everyone in the transcribers group making transcriptions available at alleywear.com/allegies-extras. I'll link it in the show notes.
βNow, if you stick around to the end of the episode, tell you secret. This week, my friendβ
Simone Yatch was in town. And I was telling her that I wish there was a word for when you try to improve something, but you make it way prettier. Essentially, a word for one of those things where you want to make something good and somehow it would have been so much better if you had just not. In the etymology episode, I was talking to Helen Salzman and I pitched maybe a bon mal, like French for Good Bad, or Greek, like Voivelap, anyway. I told Simone, I wish those are words, and she said,
there is, in Swedish, it's called a bear favor. And it's from a fable about a bear, trying to help someone by chewing away a fly with a boulder on their face and kills them. So, a bear favor. Y'all, there's a word for it. I'm thrilled. It's very exciting. Okay, bye bye, pack a German college, mommyology, your dozeuology, meteorology, meteorology, no biology, no biology, no biology, zero y'all, no biology.
