Mayim Bialik's Breakdown - We’re Not Alone. String Theory Explains Aliens, Time, AI & The Hidden 95% of the Universe | Dr. Lara B. Anderson
Episode Date: July 3, 2026The Universe Is WAY Stranger Than You Think… And Physics Might Prove ItWhat if EVERYTHING you thought you knew about reality is incomplete, or just flat-out wrong?In this episode of Mayim B...ialik's Breakdown, Dr. Lara B. Anderson (theoretical physicist & string theory expert) reveals the shocking truths about our universe that most people, even die-hard science fans, completely misunderstand. From hidden dimensions to time behaving differently across the cosmos, this conversation will change how you see existence itself.Dr. Anderson breaks down:- Why string theory could be the missing key to EVERYTHING, uniting quantum mechanics & relativity, redefining reality itself- Real explanation behind dark matter & dark energy, and what might actually be powering the expansion of the universe- Unsettling truth about the fate of the universe: are we heading toward another Big Bang, or total catastrophe?- How physics proves time isn't universal and why it behaves differently depending on where you are in the universe (and what that means for time travel)- Difference between multiverse vs. extra dimensions, and the actual physics suggesting both could exist- What other dimensions might look like & why we can’t directly see them…yet- The true shape of the universe- Why studying the Big Bang might tell us exactly where everything is headed next- How math lets us explore realities we physically can’t access due to technological & budget limits- What exists beyond our solar system & how much we still don’t understand- Why life almost certainly exists elsewhere and what discovering alien civilizations could mean for humanity- Could AI finally solve the impossible math behind string theory?- Possibility of undiscovered particles that could completely rewrite physics- Surprising truth about The Big Bang Theory TV show from a physicist's perspective - what it got right & what physicists complained aboutThis isn’t just physics. It's a full-on reality check.If you’ve ever wondered what the universe is really made of, where it’s going, and whether we’re just scratching the surface of something far bigger, this is the episode you can’t afford to miss!Receive a free LMNT Sample Pack with purchase just visit https://drinklmnt.com/mayimHead to https://www.Superpower.com and use code BREAK at checkout for $20 off your membership. Unlock your new health intelligence. 100+ biomarkers. Every year. Detects early signs of 1,000+ conditions. #superpowerpodGo to https://tidd.ly/4uVltMe and use the code MAYIM50 to get $50 off your Elastique order.Visit https://drinkag1.com/BREAKDOWN to get a free AG1 Travel Case with 7 free AG1 Travel Packs in your Welcome Kit with your first AG1 subscription, order while supplies last.Learn more about Dr. Lara B. Anderson & her work: https://www1.phys.vt.edu/~lara137/Follow us on Substack for Exclusive Bonus Content: https://bialikbreakdown.substack.com/BialikBreakdown.comYouTube.com/mayimbialikSee Privacy Policy at https://art19.com/privacy and California Privacy Notice at https://art19.com/privacy#do-not-sell-my-info.
Transcript
Discussion (0)
There are lots of things we don't understand about the universe right now.
This seems like a really big problem.
I would be very surprised if the universe isn't absolutely full of life.
I work in theoretical particle physics and string theory.
Very much the stereotypical nerd physicists from the Big Bang theory.
Early 20th century physics showed us there are more dimensions than what we see around us.
I'm totally fascinated with how organisms could arise, how they could function.
It's got mass, it's got energy, and it's not the stuff that the stars near us are made of.
There's a lot of discussion.
discussion about new proofs that are being generated in collaboration with AI.
What does it mean for this next level of evolution?
We're in a really remarkable moment.
Are these things going to be conscious?
What happens when these things become much smarter than us?
I find it really scary and really exciting at the same time.
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Hi, I'm I am Bialik.
And I'm Jonathan Cohen.
And welcome to our breakdown.
Today we're going to be speaking to an expert in string theory.
But we're not just going to talk about this incredible theory, which is a fundamental component of theoretical physics.
We're going to be speaking with Dr. Lara Anderson.
She's a professor of physics and mathematics at Virginia Tech, and she studies theoretical high-energy particle physics and string theory.
She's going to discuss the biggest mysteries of the universe, dark matter, multidimensionality, the multiverse.
What holds the universe together that we cannot see and still do?
not understand. And what does it mean to say that reality is actually comprised of more
dimensions than we can even perceive? Take a quick second and check to see if you're subscribed.
Don't miss out on all new episodes of Maim Bialek's breakdown. We cannot thank you enough.
And now it is a pleasure to welcome to the breakdown, Dr. Laura Anderson.
Break it down. Thank you so much. It is my pleasure to be here. We'd like you to start with sort of
telling us what you study and why you chose to study it? I work in in high energy theoretical particle
physics and string theory connecting to your own background very much the stereotypical nerd physicist
from the Big Bang theory. I have to say that show really did channel our people well. I appreciated
the insight into physicists that was given there. But yeah, I study theoretical particle physics
and string theory. So the work I do is theoretical, meaning I
I'd use computers and equations to try and understand how the universe works, what makes up the universe.
So what are the basic building blocks of matter, energy in our universe, and then what equations,
what laws of nature do they obey?
And for me, actually, the way I got into this was very much a sort of transformative moment when I was a kid.
I went into a planetarium at age 12 years old, and I saw a star show that had been designed by Stephen Hawking, actually,
that was about the origin of the universe, you know, the Big Bang, Black holes, expanding universes, galaxies, all this stuff.
I just thought it was so freaking cool that people could figure out stuff like that about the universe by observation and by, you know, thinking about it.
So I marched out of the planetarium at age 12 and I was like, I want to do that.
What do most people get wrong that you're trying to explain?
One thing that I think is difficult about physics is that a lot of the ideas of how you think about things,
how you ask questions, how you test those questions, they're very different than how you would
explore things in your everyday life. So when people talk about doing research on something, like that
normally means, you know, you look stuff up on the internet and you think about it and stuff.
But that process of how do you post questions, how do you then try and decide, you know,
what the answers are and unfortunately have lots of great ideas that don't work.
That's something that I think is not super appreciated.
I want to know about when you first heard about Big Bang Theory, because I'm curious sort of in the cultural vernacular, and then we will absolutely get into all of the hard science.
Did you hear about this? Did other people say, like, hey, there's a show about physicists?
I'm just like curious personally when you sort of discovered that there was a show about, because when I auditioned for the Big Bang Theory and they told me they wanted a female Sheldon Cooper, I had never seen the show.
And so I googled Sheldon Cooper and I said to myself, oh, this is like all the people I went to grad school with.
Like these are like all my friends.
Like this is how we talk.
This is how we function.
And so I found it fascinating that there was a TV show about it because I didn't know about it either.
So I'm just curious what your first foray into understanding there was a show about people like you.
I think it was probably, you know, my family, extended family saw it was like, hey, you got to check this out.
Random anecdote.
The show had been on for like a couple of years.
and I was at a physics department,
and I was hanging out like this big table full of people in my field.
And the show came up, and there was some people that were saying,
you know, this is like stereotyping physicists and this is like so unfair and stuff.
They were kind of griping about it.
But I looked down this table and like just like the perfectness of the setup, right?
You know, these were exactly, you know,
the people that were talking about going to the comic book shop and play video games
are like super into their equations.
You know, it was the sort of irony of that situation of like, yeah,
there's stereotyping us, but here we all are doing what we were doing was very cute.
When people would ask me, like, how do you feel about the show stereotyping people and, you know,
and I said, you know, there's all different kinds of physicists.
And in particular, there's all different kinds of women in science.
And I had professors that looked like models.
And I had professors that looked more like Amy Farah Fowler.
So, like, to me, like, there's all different kinds.
But I absolutely based my character on a composite of two actual.
humans in my circle who were incredible women, incredible scientists, incredible mentors. So for me,
it was a way of honoring the quirks about many of us. And yes, many of us find our way to science.
Let's go back a little bit because your specialization is mathematical physics, right?
That's right. I wonder if you can also explain a little bit about how those two sciences
come together and what's special about the work that you do. If you want to decide, you know, how
something works in physics or the universe, you sort of have two tools to try and attack that.
You can either, you know, do a measurement and you can say, I, you know, predict that when I,
you know, drop an apple, it's going to fall at this rate, it's going to hit the ground at this time,
right? You can make predictions and you can test those predictions. Or you can try and say,
let me model mathematically what I think is going to happen before you do that experiment, right?
And then hopefully you do both and see that everything agrees, both your theoretical understanding
and your practical observations.
So in the kind of work I do,
a lot of things to directly test the questions
in particle physics that we would want to understand,
you would need immense particle colliders
like the size of the solar system
to be able to smash atoms together
and directly access energy levels
and see how particles behave in that way.
So instead of being able to do that,
because we don't have the budget
for a solar system size particle collider right now,
you can also try and mathematically work through what's going to happen in all these different
scenarios. And that mathematical consistency of the number of things that you can observe about
the universe and write down and then figure out, you know, if this is true and this is true,
then how do you fit that together? What does that imply for the next thing? That type of mathematical
consistency is really powerful for ruling a lot of things out. So that's, yeah, the role of theorists
is to try and understand what should be looked for in experiments and then to make
sure that our theories as we're developing them are mathematically consistent.
Yeah, and I think that's an important point, especially for people who might be listening
and not really have a handle on a lot of these sort of larger concepts, you know, what mathematical
physics is doing and what sort of, what the theoretical world allows us to do is to study
things in a way that they can't be studied in the real world, either because of physical
limitations or conceptual limitations, but, you know, one of the things I love about math,
I'm just like, you know, a math person. Like, it's a language. It's a language that allows us to
access these different pockets of the universe that we can wonder at, but these are the ways that
we actually study what is beyond when we can't necessarily touch it or see it with the naked
eye, if that makes sense? In my field in particular, when you're asking questions about fundamental
physics, not only is there a question of, you know, the size and scale of the experiments,
but many things are really hard to visualize or to, you know, beyond the scope of what we're
familiar with. So one that comes up in string theory is this question of what's the shape of our
universe that we live in. So is our universe actually three spatial dimensions, like a box,
sort of up, down, side to side that we can see plus a time dimension, or could there actually be
additional dimensions beyond that? We have these planets, right? And because of lots of interesting
reasons, they're spherical, right? And we know that there are also, you know, in the solar
system, we know that there are other planets and that they have these kind of elliptical shapes, right?
That they kind of move around. But then if you were to ask me, like, what's beyond there? I would just
be like a lot of black and a lot of stars and a lot of planets and it just goes on forever,
right?
Right.
How close am I?
Because if you ask me the shape of forever, you know, it's like this feels like a hallmark card.
What is the shape of forever?
I just think it goes out in like every possible dimension to infinity.
Is that a shape?
what's beyond the solar system? As you said, there's lots of galaxies, there's these big structures of, you know, like walls of galaxies, lots of empty space. And we are limited in the way our ability to probe the universe, actually by where in the universe, you know, we can see back to from the light that has reached us or more recently through things like gravitational waves that have reached us. So short answer is we don't know, actually, you know, the very far distant structure of the universe. There's parts of the universe that we don't have access to yet.
But we do know some structure about the universe.
So one of the things we know, for example, is that the universe is getting bigger.
It's expanding.
And that already is hard to visualize, right?
So if you say, like, expanding into what, right?
It's, you know, it's a three-dimensional space that's, you know, getting bigger.
So the analogy that people use is if you were to look at, like, the surface of a balloon as you were blowing it up,
if you were to draw a bunch of dots, like on the surface of that balloon, as you blew it up,
all those dots would be getting further apart from each other.
but there's no center to that expansion on the surface of the balloon, right?
So the same thing is happening to our universe is that every part is getting further away from
every other part, but that expansion is not happening in our three dimensions.
It's in some sense happening into a larger dimensional space, was one way to think about it.
What does that mean for things to be getting bigger in a larger dimensional space?
Because what I picture is kind of like, you know, if you picture a firework, like before, you know,
they kind of arc, right? That's what I'm picturing. But also, the expansion is happening
quite slowly. To me, can't it just expand out into every dimension that it's already in?
Meaning I'm picturing like all these vectors, right? And the vectors are just going out
from whatever the center is, right? And it's just like, again, this is like, I feel like a five-year-old.
It just keeps going. So here's the thing. If we were like the firewomen,
work analogy, you would need a middle of that explosion, right? You need some point in space where
like all the bits are coming away from that point. And what we see looking at the universe is there
isn't a middle like that. Every point is getting further away from every other point,
but not from like one center part of our 3D space, if that makes sense. Where is it expanding
from, right? And where is it expanding to? Because if you look at like a map, right, and you would say,
oh, if I were to zoom out, we're evolving around the sun in our solar system. But if you zoom out
and there are, I don't know how many other solar systems? Uncountably many. Right. So you don't have
one center from which things are expanding. I mean, I also, the thing that I love about
physics is also these ideas can be applied to like our human existence, right? Very much so. Yeah.
if I grow, if I grow as a human even conceptually, right?
What is the limits of human growth and expansion and expansiveness?
It's a beautiful thing.
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while we left this thread hanging, which is 3D space, maybe time.
And we speak to a lot of people who have either had near-death experiences and have gone off and experienced and come back with all this information.
And they're like, where is this?
We speak to a lot of people who leave their bodies or whose consciousness seems to leave, right, this body.
And they have experiences that often involve experiencing.
an expansiveness of their being in the universe
that they have no scientific basis for.
Meaning, if you take someone who's never studied physics,
either theoretical, practical, any kind,
what they describe is, you know, experiencing traveling,
into all of these other aspects, right, of the galaxy.
And some of it could be the things that your brain sort of fills in.
But can you talk to us about multi-demand
Is that a kind of place where consciousness can exist in a different dimension?
What are the choices for other dimensions besides, you know, the sort of X, Y, Z plane, and time?
There's this beautiful quote by Arthur Eddington, early 20th century physicist who said that the universe is not only
stranger than we suppose, but it's stranger than we can suppose. So I think it's fun to explore
some of these things that really stretch our own visualizations of how all this works.
So we were just talking about the expansion of, you know, the physical size of the universe,
just to go back to that balloon for a second to help us visualize what's about to come.
So if you imagine the surface of a balloon, right, all the parts are moving on that balloon further away.
But the expansion of the balloon isn't happening on the surface.
It's actually happening in the middle of the balloon, right?
So that would be like a two-dimensional surface, all the parts are moving away, but it's expanding into three dimensions.
So that's the kind of picture that you think of for our universe is that our universe is three-dimensional,
but it's expanding into four dimensions.
And now this is where, at least for me,
my brain kind of stops because you think,
what does it mean to have four dimensions, right?
How would we have, you know, up, down, side to side,
and whatever else is happening?
That mathematically is really easy to write down,
but our human minds, based on just all of our experience
in the world to date,
can't really visualize what that would be like.
So the analogies that you could sort of play with
as you could imagine, what would it be like if we imagined, instead of our 3D world, a 2D world,
right? What if you, you know, you lived on the surface of a table, right? What would you see?
If you were to see, like, a 3D creature move through your 2D world, you'd only see the
cross sections of that, right? Like, as it passes through your world, you'd see, you know,
as something enters, you'd see a circle of one size, get bigger and then smaller again as something
move through. So you'd see sort of a two-dimensional shadow of a three-dimensional thing.
And mathematically, you can write down exactly that same sort of structure for our universe.
You could say if there were four spatial dimensions or more, what kind of three-dimensional
shadows would we see of something that was four-dimensional that could move through our universe?
In the kind of work that I do in string theory, it's actually essential for the sort of consistency
conditions of physics that there are more dimensions than what we see around us.
And they don't all have to be the same size.
So this is another thing that's sort of hard to imagine.
When you say like size of a dimension, what does that mean?
So an analogy that I use sometimes is if you imagine looking at something like a wire, something very thin from far away, it would look like it's only a one dimensional object.
It has a length.
But if you were able to like zoom up really, really close to it, you would see that it has a thickness, right?
It has another direction to it.
It's actually a 2D surface.
So this is a question we can ask in physics is that our universe looks,
like it's three-dimensional. But if you were to zoom in really, really, really small to all the
space that we look at, could there be other, like that thickness of the wire? Are there other
directions that things could move? Other directions that energy can move into, that particles
could interact with. And then you could ask, you know, what is the consequences of that for
physics? So a long time ago, I tried to explain what I do for a living to my grandma by saying
that I wrap up extra dimensions for a living. So I wrap up these extra dimensions. I try and say,
if they were really small, what would be the consequences for physics and what would we observe?
Jonathan just sent in our little chat here a hypercube image.
And I'm going to say something very strange.
When I looked at this, it made me feel like crying, meaning I had an emotional reaction
to seeing something that is outside of the bounds of what I think.
I can perceive.
Yeah.
Does that make sense?
Being attracted to things that expand the way that we think about stuff is really cool.
I definitely felt that.
You mentioned, as of one of your guests, Mishi Okaku, you wrote a bunch of popular
science books.
And I remember reading one when I was about 13 years old.
And again, just that feeling of being like, wow, this is so cool that people can figure
this out by thinking about things, right?
That you can think about things differently and then imagine structure that you never knew
was possible.
I think we should tackle what is string theory because the layperson has heard about it, but probably doesn't quite understand how to explain it or how it's practical to them.
String theory is an attempt in one consistent theory to try and model basically all of the fundamental interactions that we see in nature.
So first I have to say, what do we mean by a fundamental interaction?
So we think that everything that we see in the universe that accelerates, speeds up, slow down, does so for basically one of four reasons that we figured out so far.
This includes gravity, so things that are holding us to the Earth right now, structure of the solar system, all that good stuff.
Electromagnetism, which is basically electrical interactions in atoms.
That's the structure of the whole periodic table.
That's why I can't put my hand through my desk right now is electric propulsion between electrons.
And then there are two other forces, the strong and weak nuclear forces that are responsible for things like radioactive decay and for holding together like the center of nuclei.
So those forces describe basically everything moving or accelerating that we see.
And we have a really beautiful framework in theoretical physics for making predictions that are extremely accurate, like accurate to 13 significant figures for how three out of the four of those work at very small distance scale.
So this is called the standard model of particle physics.
We have this great ability to describe the strong and weak nuclear forces and electromagnetism.
And we also have a description of gravity, thanks to Albert Einstein, that describes gravity as the curvature of space and time that he developed in the early 20th century.
Also an incredibly predictive, really beautiful theory.
It's why modern GPS works.
And these two frameworks for gravity and then the other three forces, they're really, really useful, really powerful and fundamentally incompatible.
If you try and sort of put together our understanding of quantum mechanics and quantum field theory with gravity, you end up getting really stupid answers.
These are so-called disastrous infinities.
So you can try and predict things that it just doesn't work.
You get wrong answers, manifestly wrong answers.
So string theory is an attempt to put all of those fundamental forces, including gravity, in one coherent framework.
And the basic idea is, what if matter wasn't little point particles, like an electron that you imagine like a little ball floating?
through space? What if instead all of the matter that we see was actually made up of extended
one-dimensional objects, like little strings? And just like a violin string could vibrate
different ways and produce different notes, string theory asks, if you had these fundamental
strings, if they vibrated in different ways, could they become different particles? So they could
they vibrate one way and be an electron, vibrate another way, and be a quark? It turns out if you
ask that sort of cute idea, like can you make different particles from different
vibrational modes of a string.
If you ask that quantum mechanically,
you actually get Einstein gravity for free.
So you end up with a theory that must be gravitational.
So these strings can only move through space times
that obey the equations that Einstein wrote down,
which is like super duper beautiful.
The catch, unfortunately, is that in order for all this to work,
you need your universe to have more than three spatial dimensions
in one time-length dimension.
So that seems like a really big ask.
So that's where the wrapping up dimensions comes in.
You could say, could this actually be consistent with experiment?
And what would the consequences of that be if it was?
If there were extra dimensions, what would it mean for physics?
What could we predict?
What could we test?
How can a string be one-dimensional?
Just having a length.
But nothing just has a length.
Well, interestingly, there are some particles in nature, like electrons,
where we think that they, you know, from what we can observe,
they seem like they're just points, right?
They're not actually.
They don't have a length.
They don't have a radius.
But we also don't have a location for that point,
meaning we have a probability that we can calculate
of where you might should hope to find that.
And same for these strings.
So you would have sort of a probability distribution
of this one-dimensional object that you're describing.
So now we have these strings that can shape-shift?
It's not that they shape-shift.
Depending on how they're feeling they're going to vibrate differently.
Okay.
I can go with that, yeah. Different vibrational modes, different masses, different charges, different properties.
I think a lot of the hippie energy workers out there are like, exactly, we've been telling you that you just need to change your vibrational frequency.
And all of a sudden, you're inside, your outside, and everything around you changes.
Why are they right or wrong?
The idea of vibrational, you know, things vibrating and having different energy levels, that's one that you can do for all sorts of different, you know, distant scales from violin strings to waves and water, all those. So in the case of the hippies, I don't know what's vibrating for them, but it's a fair question.
But how does that change our understanding of the nature of reality if things can change what they are in that way?
The consequences of that are that if you have these little one-dimensional strings that are vibrating in different ways, they're being different particles, as they move through space, the kinds of ways that they could interact with each other.
So the ways that they can, you know, join up, separate different vibrations, all of that tells you about what particles could exist and then how they're going to behave.
And that allows you, in principle, to predict lots of things.
So a big question, there are lots of things we don't understand about the universe right now.
So we know from research in astronomy that we actually don't know what the majority of the universe is made of.
This seems like a really big problem to me.
It's a really big problem, right?
So there are things that we refer to as dark energy or dark matter.
These are things that we think in terms of the gravitational structure of the universe.
There has to be stuff out there that's interacting gravitationally with everything else.
It's got mass.
It's got energy.
but we don't know what it is, and it's not the stuff
that the stars near us are made of.
So the question of, you know, what is all that energy?
What is all that matter out there
that's determining how the universe is evolving
and what's going to happen to it?
That's something that, you know,
a theory like string theory would try
and answer by positing what particles
and what forces might exist.
A fun actually observed quantity
that lots of people and lots of theorists
are thinking about
is the fact that the universe isn't just expanding,
it's speeding up.
So the question of,
of like, what's driving that expansion?
What's producing that energy?
Right?
That's a great question.
What do you mean it's speeding up?
I was just still trying to get my head around expanding like the balloon.
What does that mean that it's speeding up?
Yeah.
It means that all the parts are moving away from each other.
And the rate that is happening is, as you said, slow, but subtly increasing over time.
Again, not to quote the hippies, but everyone's saying, things are moving so much faster these days.
And it's the speed of technology, which were bombarded by information.
but to think of that being paralleled.
So there's one possible thing that could be driving that expansion,
so one maybe explanation for it,
which is the idea that empty space itself might have energy.
So in quantum mechanics, which describes how particles interact,
as you alluded to a few minutes ago,
things are sort of happen probabilistically.
So you say, you know, is a particle here or there?
You can't really say, but you can say, you know,
the odds of it doing X or Y,
you can figure out. So when you say space is empty, you have to say, how sure am I, but it's
actually empty? So could it be the case that you think you have empty space, but actually a
particle and an antiparticle appeared and annihilated and then disappeared again while you
weren't looking, right? Could it have happened in, you know, just an infinitesimal fraction of a
second? So there could be this sort of bubbling soup of particles that may or may not exist
probabilistically in empty space, and that can actually contribute energy to the universe.
And then as the universe gets bigger, you got more space. So you got more energy of this uncertainty
of these particles in empty space. And that can actually drive expansion. It can make the universe
accelerate even more. Okay, the universe is expanding. It's expanding more than it was,
right? Let's say a second ago and a year ago and a light year ago.
And it's not only expanding more, it's expanding faster.
So I can't help but think, like, what are we careening towards?
You know, when you think about sort of the Big Bang theory and you think about whatever led to the fact that, like, you know, we're all stardust and all of those beautiful notions, that's our evolution story.
What's our catastrophe story, right, that we can tell ourselves about this expansion that's how.
happening at even a more rapid pace. Like, I picture us hurling now through space, right, with some
catastrophe looming. Is that just my, you know, puny human mind? No, that's a totally fair question.
And it's one that scientists have thought about for a long time. So this is about the fate of the
universe, right? So if we, as you say, if you imagine that the universe arose from some sort of, you know,
big singularity or, you know, cosmic explosion in its past, where is it going? And there are different
possibilities that people consider, and that's very much dependent on what the universe is made of
and what's happening to it that we don't fully understand. But possibilities could include if you
don't have enough stuff in that universe, it could expand for a while, and then eventually gravity
could kind of win out again, and everything could start moving back closer and closer together
until it basically recalapses, possibly explodes again. So this would be a recalapse scenario for the
universe. You could also have an expansion, and this is what our current data sort of indicates,
is that you could have an expansion that just keeps going forever and everything gets further and
further apart and colder and colder in the ultimate fate of the universe. So these are referred to
as like the big crunch if it re-collapses or the big freeze if everything just expands arbitrarily far
apart, all the stars eventually burn out and everything gets cold and dark at the end.
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Should we be concerned?
It's going to happen a really long time from now,
much beyond the life cycle of our star.
So we won't be around to worry about it.
Some people say, like, this could be, you know,
a cycle of universes arising, getting destroyed,
and then becoming again.
So one possibility to be your universe collapses in
and you create a new Big Bang that makes a new universe.
So in this other option,
where everything keeps expanding,
it gets cold because when no one is close enough to a sun or any of those kinds of stars that are generating
the sort of heat that in our particular planetary climate keeps us alive.
Yeah, or just phrase differently that a lot of the energy in the universe comes from density,
right? You have to smush things together to make stars and, you know, things like that.
So if everything gradually gets, you know, further and further apart, you don't have, you know,
clouds that are going to condense to form stars. And so, yeah, everything eventually becomes very
cold and dark. I wonder when people talk about, you know, kind of imminent environmental concerns
and the concerns of our planet's needs. How much do you consider those kinds of needs
considering the kind of thing that you study? I think these types of concerns are so far distant
in timescales that we do not have to worry about them as humans. I mean, they're fun to think about,
But in terms of what will happen to our planet and our sun, you know, this is many, many, many
lifetimes of suns in the far distant future that you would have to worry about anything like this.
I do think it's really fascinating to ask, you know, what can we determine about this?
And can we figure out, you know, what's in the universe so we can decide, you know, what these
scenarios happen.
The specialness of star formation, the specialness of, you know, solar systems, of being in the sweet spot
for the earth such that life could form.
There's all sorts of great questions you can ask like that in physics about what it takes to get, not just life, but complexity, right?
What does it takes to build complicated things like we see in the universe?
And it's all really special.
Just to mention one kind of quirky one when we're talking about higher dimensions, if you said, I want to build a universe and I'm willing to build it in any number of dimensions, right?
Don't care.
Like what's going to happen?
If you try and build something like a universe in two dimensions, two dimensions is just too simple to actually be able to build.
rich structure like we see in the universe to be able to build stars and galaxies and stuff.
If you go up higher and you say, I want to be in four, you know, big macroscopic dimensions.
I just want this, you know, big higher dimensional universe.
It's actually things sort of generically miss each other.
It's too much space to build complicated things.
It's hard to build, you know, stable gravitational orbits like we build, you know, our solar
system out of.
So three dimensions is actually kind of a sweet spot to be able to build something.
like our universe that is complex and stable and can support stars and planets and galaxies and us.
I heard that potentially there are more dimensions than three dimensions, but potentially they
are hidden. We don't, we haven't observed them fully. How does that relate to the multiverse that
Marvel keeps showing me? This is related to this, this quantum mechanical uncertainty that we
were talking about a moment ago. So if you have a particle and you say, I'm going to, you know,
take this very small electron, right, that makes up atoms. And I'm going to, you know, shoot it at a
target. Okay. I'm going to ask, where does this thing hit? If you try and do that, it isn't like
shooting a, you know, string of billiard balls at a target. You don't just get, you know, here's where
each ball hit. What you find is this distribution of, you know, almost like a wave of how things could
have behaved. And that is in quantum mechanics, the fact that we don't know for sure where these
particles are, that they are extremely hard to pin down. And so that theoretical probability
distribution of like, these are all the possible things it could do, that actually gets realized as a
physical measurement of this weird distribution of possibilities being realized as, you know,
the results of where did my electron hit when I shot it at the screen. So people have tried to
ask, you know, can I interpret those different possibilities? Is the particle here? Is it there? Is that some
sort of like physical real thing, right? Is there one universe where it's here and there's another
universe where it's there? That's the idea of the multiverse. I personally think that that's not
really a scientific question yet because we have no ability to probe those in multiple, you know,
versions of a universe happening simultaneously. So there's no real measurement we could do that would
distinguish that from just the mathematical notion of probability that we're using. But it's a really
cool thought. And I like all the multiverse movies too, say, you know, there's one version of me in
another universe that's doing something different. When I got to study this, you know, and we got to
think about parallel universes and things like that, you know, it's fascinating, not just, again,
kind of conceptually when you think about what it means for different selves of you,
but this notion that there are different versions possible of every reality that we also think
that we can see, from people who have had near-death experiences to physicists to, you know,
psychologist saying, you know, everything that we're seeing is what we're perceiving and what's being
projected upside down on the back of a, you know, retina that, you know, sends information and,
you know, through all of these different cells. But, you know, the easiest example is, you know,
when we describe a color, that's actually the one wavelength that's not being absorbed, right,
by an object. But Donald Hoffman talked about, you know,
what if we see reality as we're already wearing the goggles, right?
This is the VR experience, right?
Yeah.
And so I think when we think about it in terms of particles,
in terms of probability, in terms of the double split experiment,
it's exciting and it's exciting in a creative way.
And obviously, people who are, you know,
creating science fiction and talking about these things
get to take it to all these different levels,
but we also get to talk about sort of the mathematical level,
which is, I think, equally entertaining.
You can't really have one without the other
and that you need to be able to explore these ideas, right?
If things are just, you know, only explored in a lab
or only explored in mathematics,
that isn't the thing that captures people's imagination.
So I'm very grateful to marvel for exploring all this too.
And in terms of, like, the physical consequences of this,
you know, there's a lot of current research
in things like quantum computers
where people are trying to like revolutionize computing
and cryptography and all these things
that will have really big real-world implications
that are based on this sort of, you know,
composites of reality and all this uncertain probabilistic behavior.
Many people who, let's say, experience flashbacks from trauma,
describe it not as a memory, but as being placed in a completely different time.
And their bodies, their thoughts, in many cases, their physicality,
responds as if it is in a different epic of time. And obviously, that's not proof of anything. That's not
the way we decide things in science. But I wonder if you can talk a little bit, for example,
about the difference between remembering something and having, you know, an experience of being in a
completely different time frame. Is that kind of time travel with a lowercase T? Is there another way to
imagine that we can experience time in a nonlinear fashion?
One of the things that early 20th century physics showed us in a really remarkable way is that
there is no universal notion of time for the whole universe.
This is very much a local thing that is based on how we're moving and where we're positioned
and that clocks will tick differently all over the universe in different scenarios.
So to give a couple examples that one might have heard of, if you're moving really, really
fast. So, you know, if you're in your rocket ship and you're zooming off to another planet,
this is Einstein's famous twin paradox where, you know, you say you have two different people,
twins, one of them gets on a spaceship and moves very close to the speed of light far away. One of
them stays on Earth. They come back and they are different ages. How is that possible?
That's something that really is possible in physics, that clocks do not have to be universal.
Another example is that in your, when you're near very strong gravitational field, so if you
were in, you know, a planet that's really close to a very large black hole, clocks will tick
differently on that planet than they would, you know, here on Earth. And so you can have
manifestly, extremely different perceptions of time between different observers and different parts
of the universe doing different things. And that can come up with all sorts of, you know,
paradoxes and contradictions that aren't really contradictions, but seem like it, because of just
how non-un universal time is. So I think that's a neat thing, that, you know, time doesn't mean something
for the whole universe, right? You can't just like say now and then that's a universal thing
that everybody gets to agree on. The question of can you go back in time? So is, you know,
time travel possible? Lots of physicists have thought about that over the years. And yeah,
I'm not going to be the definitive word on that. Some people are still, you know, thinking
concretely on this. But we can say that if you try and write down a physics theory that allows
time travel, that allows these so-called closed time-like paths where, you know, you go back in time
and do something. Physics breaks down really fast. You end up with all sorts of nonsense answers.
So this is the famous, you know, you're going to go back in time and shoot your grandpa,
and then you get a logical contradiction, right? That happens in physics all over the place
if you have time travel in the sense of you get to go back. So in terms of consistent physics
theories, I would say there is no universally agreed upon consistent physics theory that allows
time travel. It seems to be really hard. The universe seems to protect itself really strongly
against such things.
Does that mean that, you know, that's absolutely the case?
Maybe there's some clever way that this can be done
that we don't know about yet.
Is it possible that one of these other dimensions
that we get to think about holds an experience
or holds things on a time scale
that don't have to exist in a way that would impact the physical world
so that we wouldn't be dealing with this possibility
of kind of physics falling apart?
But just as people with, you know, you could call it extrasensory perception or people who are
incredibly intuitive, right? People who are in touch or tuned in, right, to other, for lack of a
better word, frequencies, right? Is it possible that there are experiences or people who have access
to some other plane where this information exists and is accessible, but doesn't have to
obey all of these other physical rules of the linearity of time?
The neat thing is, is that when you mathematically model this, the rules apply to everything.
So whether it's an extra dimension or is an ordinary dimension, you don't get to like get a
get out of jail free card just because it's not something that you can observe in our current
universe.
So in that sense, I would say that, you know, things like time travel in the literal back to the future
kind of sense, you don't get helped by having extra dimensions in that.
Indeed, people have actually asked, could some of those extra dimensions be time-like?
So could you have more than one time, right?
That's a cool concept.
And again, that breaks down real fast.
It gets really hard to do consistent physics in that scenario.
But people are still thinking about it.
And then, you know, the question of what human beings can perceive, how we function consciously.
I think that's a fabulous set of questions, but not unfortunately physics at the moment.
You know, from the time that you were a little girl and fascinating.
with physics and wanting to study the cosmos and all of the incredible things that you get to study,
how has your understanding of life on other planets or life in other galaxies, how has that changed?
And how do you incorporate that into the work that you do? Because it's changed really in the
last several decades in terms of what we know, what we can know, and what is actually possible.
How has that changed your worldview?
This comment you made earlier about the sort of specialness, apparently, of life on Earth, right?
That we haven't observed life elsewhere in the universe, that we seem to be in this unique position.
My physics training has shown me that somehow that type of specialness doesn't arise very readily,
that if you have something that's possible, if you can build complex molecules,
if you can build human beings and consciousness, the idea that that would only happen once in the universe seems
almost infinitesimally unlikely to me. So that is not a proof that life exists elsewhere in the
universe, but I feel like, of course, life must exist elsewhere in the universe, because,
frankly, we're just not that special. And throughout the entire history of humanity, when we
thought we were, right, when we thought that the sun orbited around the Earth, right, we've been
consistently dethroned in terms of how special we think we are. So I don't have any proof of life
outside of Earth, but I think that almost certainly, I mean, the universe is so vast and there's so many
possibilities and such a rich environment to create complex systems and life. I would be very
surprised if the universe isn't absolutely full of life. And just to riff on that in one other
direction, the other thing that I think the modern moment is teaching us is even with the advent
of things like machine learning, we're beginning to understand that human consciousness
maybe isn't that special even, right? That, you know, you can build very complex networks
that begin, and again, I'm not saying AI is thinking yet, but we're beginning to understand
understand better how you get things like thought out of complex systems. So I think that's a really
neat scientific question as well. There's something about speaking to someone who literally lives
in the math of physics having this kind of conversation that is so thrilling to me.
Because I want to know what does that mean, you know, if you kind of like take off your professor
hat, right? And then you put it back on. Like, what are you picturing? Do you picture carbon-based
beings. Do you picture silica-based beings? Do you picture, you know, as many people have talked about,
that if something is out there and we're not aware of it, which I'm assuming we're not in the
practical sense, it likely is thousands and thousands of years ahead of us. It may actually be
some artificial intelligence that isn't even recognizable, you know, as some sort of, you know,
green or gray, you know, kind of alien. What do you imagine and what are you allowed to imagine,
given your credentials? Again, our view of what's possible for life, for complexity, for how things
would form and behave is so limited by what we've experienced. So I don't know what I visualize,
but I very much am excited by the idea that there could be things just so wildly different
from us, not necessarily in terms of their building blocks. Carbon is a pretty great way to build
complex stuff. It's a lot better than silicon, actually. So, you know, maybe that is the ubiquitous way
that this arises in the universe. But in terms of, you know, how organisms could arise, how they could
function, communicate, what would be important to them, how they would explore the universe. I think
all bets are off, and I'm totally fascinated with what that would look like. I'm particularly
interested, it seems really hard for, you know, organisms to cooperate, to survive, to take care
of their planet, to move, you know, wider in the universe. So if other civilizations have done that,
that would be fantastic to learn about. I mean, I think it would also be fantastic to learn about
civilizations that aren't constantly going to war with each other, you know, because like when
I think about sort of our experience, when I think about what's possible when people come together,
when systems come together. I mean, even think of our body, right? It's,
It's an entire organism of cooperation, right?
When you extrapolate that, the possibilities are literally endless.
And if you think of sort of like love and peace and hope as things that we can actually experience,
I would love to know, right?
Has someone figured this out?
Because we clearly have not.
And, you know, there's been this question in the structure of the universe,
like, why have aliens not communicated with us if there's other lines?
in the universe. And A, the space issue, it just is so big and it takes so long to send signals
that that's, you know, one explanation, but also, you know, as other people have commented,
you know, maybe when we go a new place, we don't, you know, lay down on the floor and try
and talk to the ants right away. Speak for yourself. Maybe we should. Can you talk a little bit more
about your understanding of machine learning? Again, you've been, you know, a professional in the
field that is so impacted by a different understanding of how we understand the universe, because for so
long, we've tackled it one way. And we're now in this entirely new era. And one of our, you know,
our main interests in talking to Dr. Kakou was about how all of these kinds of theories are now being
computed, contemplated, and really crystallized in a completely different way with quantum computing.
How do you frame sort of this notion of machine learning language models?
You know, are we creating thought or are we creating an artificial representation of our limited understanding of thought?
I think no one really has the answers to that question yet and lots of smart people are trying to answer it.
But I think that actually, like, as of this year, we're in a really remarkable moment for artificial intelligence as it impacts science.
So for me personally, for a number of years, I've been involved in work that involved numerically approximating solutions to things.
So you have like really hard equations that you need to solve that you don't know how to solve.
And so you come up with schemes in a computer to run code and to simulate how a solution might look.
And a few years ago, you know, people started using neural networks.
We tried to use some of these techniques of machine learning to make solving these equations more viable.
And, you know, the immediate progress was really remarkable.
Things were so much faster.
It was this really powerful new computational tool.
And then you have things like these large language models, the transformer architecture
of machine learning.
You know, this comes in with things like chat GPT and quad.
And at first, you know, it seems like, okay, yeah, maybe you can use this to write your
college essay, but, you know, it's not going to be impactful for science.
But really, just in the last six months, in my field, at least, this is really starting to
change the way that people do physics and mathematics.
and the type of results that you're able to get out of these large language models,
the question of whether they're capable of innovating in science,
can they actually reason, can they come up with new ideas beyond what human beings have come up with?
This is a very serious question that lots of people are now tackling.
And certainly, I would say these machine learning tools now, the large language models,
they're at the point that you can have a conversation with them about these ideas,
a productive scientific conversation like you would with a colleague.
and they're able to generate new ideas.
So mathematicians, there's a lot of discussion in the math literature about new proofs that are being generated in collaboration with AI that humans might not have come up with before.
In my field, people are really trying to push this to be able to come up with new paradigms, new ways of thinking about things.
And I find it really scary and really exciting at the same time.
So like, where's this leading?
Are these things, you know, going to be conscious?
Is there a notion of, you know, general artificial intelligence that's,
close by. What are we going to do with them? I'm not sure, but I think things are changing really
fast at this moment. Again, this is the second time I've been kind of like moved in a very special
way in talking with you because, I mean, I'm just thinking about, you know, even in our lifetime,
the way things used to be done. Like when I was in grad school, I talk often with younger scientists
about what it was like to fill out IRB forms. If you need to be done, if you need to be done, you know,
needed to work with human subjects, you had to produce four Xerox copies and then like the printer
was out of, you know, toner and you had to like go to a different printer with your copycard
to take the forms to an office. Like it was just, this was just to get approval to do your research.
Or when I think about what it was like to write a grant, most of our time was spent doing things
that now you do not have to spend time doing. So I'm thinking, gosh, what can we do with even just
the brain power that is now open to us because of the systematic, you know, methodology we can now
use to do just, you know, kind of logistical things. Beyond that, I think of things like, what's it
called when people have like AI psychosis and people think that they have all these amazing
ideas and in many cases they do. But I'm thinking like, gosh, how much of science now has kind of like
blown this wide open. And I don't mean to use your own kind of metaphor, but it's as if it's
expanding out in every dimension at increasing speed. It's really changing the landscape of how we do
science and the questions that we can get answers to, the way that we can ask them. And, you know,
a lot of people, myself included, you know, when these first, these tools were first available,
I sort of viewed it as, you know, a clever way of predicting the next word, right? You know, you just
it's pattern matching, it's saying, okay, when people write letters, we know, what word goes
where. But it's clear that they've become a lot more than that. There's a lot more possibility
there. And to come back to a previous point about, you know, human beings not being that special,
it's also clear that if you build networks that are sufficiently complex, you know, in some sense,
human brains are predicting the next word too. We're, you know, we're running on algorithms,
although we don't know it. And so where that stage of, you know, you have a network,
that is a machine that is connecting in certain ways. What level of complexity does it begin to think?
And then also taking a human brain apart the other way and saying, how does consciousness mechanically
form? What are the rules for how we became what we are? I think those are a fascinating set of
questions. And I think we're starting to get new insight into how those things hook together.
When you look at something like trauma and people say, why do I keep picking people who hurt me?
Why do I keep going down this same path? It's because your brain knows
this is comfortable, this is the groove,
we've created this pathway, and we're going to keep hitting it.
And if someone triggers it in some other way,
you get this notion of,
why am I having the same reaction,
even though I know I'm safe, right?
That is what this complex system does,
and it's the best that it can do.
But what's fascinating is that, you know,
when we get into healing modalities,
and especially when Western medicine says to people,
I don't know why that's wrong with you, take this pill, right?
Other healing modalities say there's another way to think about it.
There's another way to create grooves in the brain, right?
So when you think about AI in this sense, it's yet another level of creative conversation
that we can be in.
I mean, there's something that's so romantic to me, though, that I need to get rid of,
that romantic notion of there's these theorems and we can't figure it out and like,
what's your favorite math question that can't be solved?
the notion that that might also be a thing of the past to a certain extent.
What happens when theories are no longer theories but they're actual things, right?
When we talk about the theory of relativity, we talk about string theory.
What is that like for you to enter, you know, an era where there may not be as many unknowns?
What does it mean for this next level of thought and evolution for us?
So one question that I know
mathematicians and physicists are taking very
seriously is what happens when these things
become much smarter than us?
Right? So right now I can have a conversation
with a large language model
about my research and I still know more about my research
than it does and so it will
hallucinate, it'll make mistakes and I can be, no, that's not right
and then it says, oh sorry, I'll fix it, you know, right?
But it could very readily
become the case soon that
computers, you know, these AI could generate theorems. They could generate theories, as you're
describing, that are right, and maybe it's hard for humans to decide if they're right or not.
So there's actually a really strong community coming in the mathematics community, which is
trying to basically write code to make algorithms that can verify mathematical proofs that might
be too complicated for humans to understand. So they're basically trying to build the
architecture within machines to try and verify machine's own theorems so that if it's too tough
for us, we can still have some way to trust it, which is not a problem that I thought we were
going to be having anytime soon. But here we are, right? So this question of, yeah, what do we do
when they tell us this is the right answer and we don't know if they're right? We're too stupid.
We're like Neanderthalensis and Homo sapiens is like, I know what to do. Go here. Meet with this
person, like, mash this up and it'll be tasty. We're going to be like the Neanderthals.
Or hopefully not, but like, how do we, how do we navigate that, right? That's a really tricky
question. And I think we're already getting hit by that of how do we decide, you know, there's the whole
like ethics issues of how all these tools are used, but also just the practical of if you have this
really powerful tool, how do you guide it toward discovery? What questions do you ask it? Do you believe what
it says? How do you figure that all out? I can't help being struck by the fact that, you know,
Every generation believes that they know things that the previous generation didn't understand, whether it's rock and roll, whether it's, you know, computer technology.
What I'm dealing with, and I think what Jonathan also is dealing with, I have a 17-year-old and a 20-year-old, and Jonathan has an 18-year-old.
But they know a lot more than I do about certain things.
And the basis of my parents' parenting was we know more than you.
And when you think you know more, we're going to put you in your place.
And what I now have, and this has literally happened in one generation,
I know have children who in many ways are still absolutely children.
I think I definitely have a lot to teach them.
But in one more generation, we may have a situation where
the knowledge scales are being tipped in ways that feel a little bit scary. Go five generations ahead.
This thing is expanding in every direction at a rapid pace. I think it doesn't even take a generation to
ask that question. Honestly, I think the space of change is so rapid that all of us, regardless of
our age, are going to be in that position of having to grapple with something wildly new.
And I definitely, I sympathize with what you're saying. I help my parents through the technology
transition, I can already see ways that, you know, younger people are much more adept than I am
at certain things. And I think, yeah, these brand new tools, like this is just exponentially fast.
And so what does that look like? How do we keep up? What do we do with it? How do we do that
responsibly? It's a tough set of questions. Yeah, the only thing that makes me feel better is that
very soon and possibly in my lifetime, my children will see what it's like to be told that they don't
know what's going on. And also the question of access, right? If you have these powerful
tools like how do we make sure that that they are available to everybody and that people do get to
use them or that they're used for good and not for evil right in the comment i mean i feel like many
aspects of our existence feels like we're in a comic book you know in terms of the the language that
certain leaders use it feels like very comic book villain but this notion of you know even the the
current boundaries that we're trying to put around technology that can hack into every system
on our planet, right? How do you control and regulate that when it's being devised to be used for
all of these other incredible things, you know? Two very important questions. The first, if people are
only listening, you have some equations behind you on the blackboard. I do, yeah. What are they about?
These are about geometries for extra dimensions. So if you say, like, what could the shape of these extra
dimensions be and they have to be really small so we don't see them, but they can be wrapped up in
all sorts of weird and wonderful ways. That will change the physics that you could get out. And so
we write lots of equations to try and describe what those dimensions look like, what would the
consequences of their shapes be, and things like that. What are our choices for shapes?
Because I tap out at like a bucky ball. So again, it's really hard to visualize because they involve
more than three dimensions. So in string theory, the common
extra dimensions that we we posit involve like for example six extra dimensions and they can have
holes and all sorts of a very weird and wonderful structure. Very simple examples range from things
like a donut shape for the extra dimensions. You could have a little torus all the way up through
very very crazy knotted geometries, things that are called Kalabiao manifolds. So there's yeah,
there's a bunch of weird configurations. That's actually one of the aspects of my research.
is try to say how many different shapes are possible. And we actually don't know at present if there's
a finite number of shapes that are allowed or if it could be infinite. What do you hope you're going
to discover by understanding the shape of these other extra dimensions? Like what unlock does that
provide for us? Long term, we'd love to know these questions about like what's in the universe,
what's dark matter and dark energy, how many particles could exist, how do they interact with
each other. So the shapes of these extra dimensions in string theory impact things like what literal
particles we would see. So, you know, we know that there are things like quarks and electrons.
If you were to, you know, zoom in with your super powerful microscope, smaller and smaller distance
scales, you can ask, are there other particles? You know, what would their properties be?
And also structure of like these questions we ask, like, what is the shape of the universe?
Why is it expanding? What's going to happen to it? All of those questions are things that, in
principle of theory like string theory could try and give you. The short term is we need to understand
what are the rules for extra dimensions first, and then we can ask, you know, what would particle
physics see? There's actually some fun visualizations you can do of if those extra dimensions
were so small that we couldn't see them, but still big enough that say very small particles could
interact with them. You could imagine like, you know, at the atomic or subatomic scale, you had two
atoms that are interacting, you know, two particles that are colliding with each other. They might
lose energy into those extra dimensions or you might, you know, if they're described as a wave,
you know, part of that wave might tail off into an extra dimension. So you can try and do experiments
to see, you know, could that be measured? Can you see that deficit of energy or, you know,
how things might behave in that way? So what is your favorite shape? I would say these Calabia
iae manifolds are really fun to play with. There's a lot of possibilities for, you know,
their twistiness, their holes, their structure. So just in terms of like,
fun shapes to, you know, manipulate, look at to, you know, poke holes in.
Clubiaz are pretty fun.
I've never asked anyone this next question in over 350 episodes, but it feels like I need
to ask you.
Have you asked me this?
Nope.
Okay.
If you could have one superpower, what would it be?
Oh, man, that's a great question.
Right now, at this moment in my life, I want the ability to like pause time for everybody
except for me.
And I'm doing that because I just feel super swamped.
I got way too much going on.
I want to be able to like just pause all the things and then take my time and do everything and enjoy and then restart it, you know, unpause the universe when I'm ready to get back into things.
That would be a great superpower.
Dr. Anderson, thank you so much.
This has been really, really wonderful to speak with you.
Are you anywhere that you'd like to tell people to find you on the interwebs?
I have a website.
I would say, yeah, check out Virginia Tech Physics.
Amazing.
Thank you so much.
We really appreciate your time.
Thank you so much for having me.
my pleasure. Quick review. A lot of dark energy out there. A lot of dark matter. A lot of stuff.
Every time we speak to a scientist, we basically figure out that they don't know a lot of things.
That's the take-on message. This lady didn't know a lot of things we asked her.
They know a lot of things, but they also discover they don't know a lot of things.
You know, I think that's an unfair assessment of Dr. Anderson, who clearly knows a lot of a lot of things.
I'm not saying I know more things.
No, but I think, well, no one is saying that.
But I think what's interesting is when we speak to people in theoretical physics,
in the theoretical realms, like the fact that, you know, I was thinking like,
what does her lab look like?
Probably exactly what we saw.
A chalkboard and a lot of scratch paper and a computer.
You know what I didn't ask her if she dreams in equations.
I really appreciated her framework for what it's like,
to operate in this era of science.
Because like I said, when you picture her as a little girl
being like, I wanna study that,
and then you get into the field at a time
when the technology has shifted so much.
Everything we do about how to explore everything,
it's literally expanding out in all directions.
That's very true.
And the final thought that comes to my head
that I'll leave us with is if Amy
and Sheldon were on air right now and they were having date night and they were interacting with
GPT. You can imagine them arguing and fighting with the current large language models.
I mean, Big Bang Theory happened at a time that was so special that likely could not have existed
right now with the capability and the framework that we have for physics, for sure.
I think both of you would be very upset with GBT.
Really, really fun episode.
And yeah, from our breakdown to the one we hope you never have.
We'll see you next time.
It's my and B.R. X breakdown.
She's going to break it down for you.
She's got a neuroscience PhD or two.
One fiction.
And now she's going to break down.
It's a breakdown.
She's going to break it down.
