Lex Fridman Podcast - #116 – Sara Seager: Search for Planets and Life Outside Our Solar System
Episode Date: August 17, 2020Sara Seager is a planetary scientist at MIT, known for her work on the search for exoplanets. Support this podcast by supporting our sponsors. Click links, get discount: - Public Goods at https://pub...licgoods.com/lex and use code LEX - PowerDot: https://powerdot.com/lex and use code LEX – Cash App – use code "LexPodcast" and download: – Cash App (App Store): https://apple.co/2sPrUHe – Cash App (Google Play): https://bit.ly/2MlvP5w Episode links: Sara's Twitter: https://twitter.com/profsaraseager Sara's Website: https://www.saraseager.com/ The Smallest Lights in the Universe (book): https://amzn.to/3g3LfHA If you would like to get more information about this podcast go to https://lexfridman.com/ai or connect with @lexfridman on Twitter, LinkedIn, Facebook, Medium, or YouTube where you can watch the video versions of these conversations. If you enjoy the podcast, please rate it 5 stars on Apple Podcasts, follow on Spotify, or support it on Patreon. Here's the outline of the episode. On some podcast players you should be able to click the timestamp to jump to that time. OUTLINE: 00:00 - Introduction 05:32 - Falling in love with the stars 09:55 - Are we alone in the universe? 15:27 - Seager equation for number of habitable planets 27:48 - Exoplanets 34:44 - Earth-like exoplanets 40:43 - Intelligent life 52:34 - Number of planets per star 55:09 - Space exploration 57:36 - Traveling to Proxima Centauri 1:00:52 - Starshade 1:07:34 - Using the sun as a gravitational lens 1:09:44 - Starshot 1:12:45 - Rogue planets 1:15:44 - The Smallest Lights in the Universe 1:30:15 - Book recommendations 1:37:48 - Advice for a young person 1:39:29 - Meaning of life
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The following is a conversation with Sarah Seeger, a planetary scientist at MIT known for her work
on the search for exoplanets, which are planets outside of our solar system.
She's an author of two books on this fascinating topic.
Plus in a couple days, August 18th, her new book, a memoir called The Smallest Lights in
the Universe is coming out.
I read it and I can recommend it highly, especially if you love space and are a bit of a romantic
like me.
It's beautifully written.
She weaves the stories of the tragedies and the triumphs of her life with the stories
of her love for and research on exoplanets, which represent our hope to find life out there
in the universe.
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As a quick side note, let me say that
extra-tress your life, aliens,
I think represent our civilization longing
to make contact with the unknown.
With others like us, or maybe others that are very different from us, entities that might
reveal something profound about why we're here.
The possibility of this is both exciting and, at least to me, terrifying, which is exactly where we humans do our best
work.
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And now, here's my conversation with Sarah Seager.
When did you first fall in love with the stars? I think I've always loved the stars.
One of my first memory is of the moon.
I remember watching the moon, and I was in the car with my dad, who my parents were divorced,
and he was driving me and my siblings to his house for the weekend.
And the moon was just following me. Just had no idea why that was.
Yeah, so like looking up at the sky and there's this glowing thing, how do you make sense of the
moon at that age? At age like age five, there's just no way you can. I think it's one of the great
things about being a kid. It's just that curiosity that all kids have.
You know, I was thinking because there's these,
that all kids have. You know, I was thinking because there's these
almost out there ideas of
that our Earth is flat floating about on the internet.
And it made me think, you know, when did I first realize that
the Earth is like this ball
that's flying through empty space?
I mean, it's terrifying, it's all inspiring. I don't know how to make
sense of it. It's hard because we live in our frame of reference here on this planet.
Yeah. It's nearly impossible. None of us are lucky to go to see the curvature of Earth.
I mean, do you remember when you realized, understood like the physics, like the layout of the solar
system? Is it, was it like, did you first have to take physics
to really, like high school physics
to really take that in?
I think it's hard to say.
I had this book when I was a child.
It was in French.
I grew up in Canada where French is supposedly taught
to all of us English-speaking Canadians.
And it was this French book in French,
but it was about the solar system.
And I just loved flipping through it.
It's hard to say how much, you know,
you or I understand when we're kids, but it was
really great book.
What about the stars?
Why don't you first learn about the stars?
I have a, like, I do have this very incredible distinctive memory.
And again, it had to do with my dad.
He took us camping.
Now my dad was from the UK and he was the type who you'd find wearing a tie on weekends.
So camping was not in his fear.
It's his comfort zone.
We had a babysitter.
Every summer we had a babysitter.
And one summer we had Tom.
He was barely older than we were.
He was 14.
My brother was 12.
I would have been 11 or 10 maybe.
And we went camping because Tom said camping is the thing.
We should try it.
And I just remember, I didn't aim to see the stars, but I walked out of my tent in the middle of the night and I looked up and
Wow so many stars
The dark night sky and all those stars just like screaming on me. I just couldn't believe that
Honestly, like my first thought was this is so incredible mind-blowing like why wouldn't anyone have told me this existed
Can anyone else see this? Have you had an experience like that with anything?
Yeah I've had that I mean I don't know if maybe you can tell me if it's the same. I've had that
with robots. There's a few robots I've met where I just fell in love with this. Like is anyone else seeing this? Is anyone else seeing that Here in a robot
is our ability to engineer
some
Intelligent beings
Intelligent beings that we could love that could love us that we can interact with in some rich ways that we haven't yet discovered
like a almost like when you get a puppy. you need to have a dog and there's this
immediate bond and love and on top of that ability to engineer it, it was, you
know, I had to just pause and hold myself. I imagine I don't have kids, I
imagine there's a magic to that as well, where it's a totally new experience.
It's like what? Well, yeah, the stars though, unlike kids or the puppy, it's only a good thing.
So you felt you weren't terrified. Like it's just to me, when I look at the stars,
it's almost paralyzingly scary. How little we know about the universe, how alone we are.
I mean, somehow it feels alone. I'm not sure
if it's a, it's just a matter of perspective, but it feels like, wow, there's billions of them out
there. And we know nothing about them. And then also immediately to me, somehow mortality comes into
it. I mean, how do that make you feel at that time? I think is a child without articulating it. I
felt that same way.
That feeling.
Just like, wow, this is terrifying.
What's out there?
Like, what is this?
What does it mean about us here?
Now, you're a scientist, an exo-world class scientist, planetary scientist, astronomer.
Now, I'm a bit of an idiot who likes to ask silly questions.
So, some questions are a little bit in the realm of speculation, almost philosophical,
because we know so little.
And one of the awesome things about your work is you've actually put data in real science
behind some of the biggest questions that we're all curious about.
But nevertheless, many of the questions might be a little bit speculative.
So on that topic, just in your
sense, do you think we're alone in the universe, human beings? Do you think
there's life out there? Well, Lex, the funny thing is, is that as a
scientist, I so don't even want to answer that. You really? I will answer it
though. But I just love to say you resisted naturally. Yeah, we naturally
resist that because we want numbers and hard facts and not speculation
But I do love that question. It's a great question and it's one we all wonder about
But I have to give you the scientists answer first. Yeah, sure which is we'll have the capability to answer that question
Soon even starting soon. How do you define soon? How do I define so much happened in the last hundred years?
soon. How do I define so much happened in the last 100 years? Right, right. And there's a difference, right? If it's 10 years or 20 years or 100 years, yeah, there's a difference in that. Well,
soon could be a decade or two decades. And the answer to the journalist usually don't like that,
or the people want like tomorrow, they want the news. But what it's going to take is telescopes,
space telescopes, or very sophisticated ground or space telescope
to let us study the atmospheres of other planets
far away and to look what's in the atmospheres
and to look for water, which is needed for life
as we know it, to look for gases that don't belong
that we might attribute to life.
So we have to do some really nitty gritty astronomy.
So the promising way to answer this question scientifically is to look for hints of life.
That's where many of your ideas come in of what kind of hints might we actually see about
this life?
Right, right.
That's exactly what we need to do.
And I like the word you chose hint, because it's going to be a hint.
It's not going to be a 100% yay we found it.
And then it will take future generations to do more
careful work, to hopefully even find a way to send a probe to these distant exoplanets
and to really figure this out for us.
I mean, we'll talk about the details. Those are fun. But like, the back to the speculation
the zoomed out big pictures. The zoomed out big picture is yes. I believe absolutely there is life out there somewhere
because the vastness of the universe is incredible.
It's so breathtaking.
When we look at the night sky,
if you can go to that dark sky,
you can see many, many hundred or even,
if you have good eyesight and you're somewhere very dark,
you could see thousands of stars.
But in our galaxy, we have hundreds of billions of stars
and our universe has hundreds of billions of galaxies. So think about all those stars out there
and even if planets are rare, even if life is rare, just because the number of stars is so huge
things have to come together somewhere, some place in our universe. Yeah, it's amazing to think that somebody might be looking up on another planet
in a distant galaxy.
I have to interrupt your reverie and get back to in our lifetime at least the short term.
We have to, we only have the nearest stars to look at.
It's true that there are so many stars, so many hosts for planets that
might have life. But in the practical question of will we find it, it has to be a star
quite close to Earth, like a few light years, tens of light years, maybe hundreds of light
years. And by the way, yeah, you've introduced me to a tool of eyes on exoplanets, I think
that NASA has put together. Eyes on exoplanets. Eyes on exoplanets, I think. That NASA has put together.
Eyes on exoplanets, so we can be software.
You can get a lot of things.
But anyway, can you give a sense of like who our neighbors are?
You said hundreds of light years,
like how many stars are close by?
Like what's our neighborhood like?
We're talking about five ten stars
That we might actually have a chance to zoom in on
I'm talking about maybe a dozen or two dozen stars and those are that's with planets that look
Suitable for us to follow up in detail for life, right?
One thing that's really exciting in this field is that the very nearest start to earth called Proxima Centauri. It's part of the Alpha Centauri star system.
Oh, name by the way. Yeah, Proxima.
Whoever names them. Nearby. Okay. But it sounds cool.
The Proxima Centauri appears to have a planet around it. That's an Earth,
about an Earth mass planet in the so-called habitable zone,
or the Goldilocks zone of the host star. So think about how incredible that is,
like out of all the stars out there, even the very nearest star has planets and has a planet
of huge interest to us. Yeah, okay, so if we talk about that planet, what does it mean to be,
What does it mean to be, maybe possibly habitable? You know, what is, how does size come into play?
How does, you know, what we know about gases and what kind of things
are necessary for life?
You know, what are the factors that you make you think that it's
habitable?
And by the way, I mean, maybe one way to talk about
that is people know about the Drake equation, which is a very
high level, almost framework to think about what is the probability
that correct me from wrong that there's life out there. And
intelligent life, I think, I don't know. But then the equation named after you now,
which I think nicely focuses on the more achievable
and interesting part of that question,
which is on whether there is habitable planets out there
or how many I guess.
What happened to the planet?
So the funny thing is was one time I met Frank Drake
and I asked if he minded if I took his equation and kind of revamped it for this new field of
exoplanet astronomy. He was totally cool with it. He's... He got told approval. Well maybe,
okay, so sorry. I'm not sure if you'd actually read the stuff about my equation, but he was cool with it.
He was cool with it. Okay, so I just said like 15 my equation, but he was cool with it. He was cool with it.
Okay, so I just said like 15 different things,
but maybe can you tell from your perspective,
what is the Drake equation and what is,
sorry, the Seagull equation?
Sure, well, the Drake equation, as you said,
it's a framework.
It's a description of the number of civilizations out there,
of intelligent beings that are able to communicate with us
by radio waves.
So if you think of the movie contact,
you've seen contact, right?
We're hoping to get, we're listening in, actually.
It's an active field of research,
listening to other stars at radio wavelengths,
hoping that some intelligence civilizations
are sending us a message.
And the Drake equation came like at the start of that whole field
to put the factors down on paper to sort of illustrate
what is involved to kind of estimating.
And there's no real estimate or a prediction
of how many civilizations are out there.
But it's a way to frame the question
and show you each term that's involved.
So I took the Drake equation
and I called it a revised Drake equation,
and I recast it for the search for planets
by more traditional astronomy means.
We're looking at stars, looking for planets,
looking for rocky planets,
looking for planets that are the right temperature for life,
looking for planets that might have life
that outputs gases that we might detect in the future.
It's the same spirit of the Drake equation.
It's not gonna give us any magic numbers.
So I'm gonna say, here's exactly what's out there.
It's meant to kind of guide, guide of where we're going.
Although the Drake equation did,
I mean, the initial equation proposed actual numbers
for those variables.
Oh, yes, the equation proposed numbers.
And you can still plug your own numbers in.
And there's this really cute website that lets you for both the Drake and my revised equation
plug in some numbers and see what you got.
So yeah.
So, okay, so what are, I mean, what are the variables, but maybe also what are like the
critical variables? So in my equation, I set out to what are the numbers of inhabited planets that show signs
of life by way of gases in the atmosphere that can be attributed to life.
I could just walk through the terms that's similar.
Sure.
The first thing I say is what are the number of stars available?
And it's not that those trillions and trillions of stars everywhere. It's what are available to like a specific search.
And so, for example, the MIT-led NASA mission test is surveying the sky,
looking for all kinds of planets, but it can also, it also has stars.
It has about 30,000 red dwarf stars.
So we just take a number of stars that are given survey can access. So that's
what number of stars is. Then I wanted to know what kind of stars are quiet. I called it
fraction of those stars that is quiet. In the case of tests, the way it's looking for planets
is planets that transit the star. They go in front of the stars, seen from the telescope.
But it turns out that some stars are very active,
they're variable, and they brighten and dim with time,
and that interferes with our observation.
I apologize to interrupt, so the transiting planet,
so you're really looking for a black blob,
essentially, that blocks the light.
We're looking for a black blob that blocks the light.
And then trying to say something about the size of the planet
from the frequency of the planet
from the frequency of the black blobs appearance
and the size of that black blob, that kind of thing.
Yeah, but let's just say that out of all the stars
there are accessible to an ever telescope,
some of them are just bad.
For whatever reason, you're not
going to be able to find planets around them.
So I need to know the fraction of those that are good.
So again, we have the number of stars,
the fraction of them that we can actually find planets around.
And by the way, is our sun, is our sun quiet?
Our sun is quiet.
Okay.
So I have actually two terms. One describes how quiet they are. And one is if we can find
a planet around that star, these translating planets, for example, not all planets transit,
because the planet would have to be orbiting that star
in this kind of plane, as viewed from you.
But if a star is, for example, orbiting in the plane of the sky,
it will never transit.
It will never go in front of the star.
So in that case, we have to have a fraction
that takes into account of that kind of geometric factor.
And hopefully it's right. I mean, you can assume that it's uniformly distributed.
Yes, we can assume and there's evidence that it's uniformly distributed. Yes.
So then the next, so all of these factors so far, number of stars accessible to whatever telescope
you're thinking about, how many stars are quiet, fractions are set are quiet, fraction that are
observable. In this case case for the geometric factor?
Those are all things we can measure.
And there's one more term in the secret equation we can measure.
I call it fraction of planets in the habitable zone.
Because believe it or not, we have a handle on that for a certain set of stars.
We know from our dekepler space telescope that operated for a number of years,
we have estimates for how many planets are in the so-called Habitl-Zone of the host star for certain type of star.
So all those we have measurable, and then like the Drake equation itself, there are some terms we can not measure.
And those ones, I call them FL, fraction of all those planets that have life on them.
Because we don't know what that is. And FS, I called for spectroscopy, the fraction that we can use our telescope and instrument
tools to look for light.
Actually FS was the ones that the planets that have life that actually gives off a gas,
a useful gas that might accumulate in the atmosphere so we could eventually observe it.
How do the FL and FS interplay? So these are separate terms?
Separate terms. And so...
So for example, you could imagine... So for example, you could imagine life,
like us humans, we breathe out carbon dioxide. But our planet Earth, we already have a lot of carbon dioxide
on it. Well, we have hundreds of parts per million, but it has a really strong signal. So us humans
breathing out carbon dioxide, it's not helpful for any intelligent beings that are looking back at
Earth, because there's already a lot of, there's already enough carbon dioxide. We're not adding to it.
So if there is life on a planet, and it's outputting a boring gas, that's not helpful for us to uniquely
identify
as being made by life versus just being there anyway, then it's not helpful. So I separated those two
terms out. Soon, I think we'll have evidence that planets that can support life at least are common.
So, okay, this is a situation awesome topic.
I have a million questions.
Okay, I know there's a little bit of speculation, but what's your sense about that, I think
FS, which is like that life would produce interesting gases that would be able to detect.
Is there one, is there a scientific evidence,
and second is there some intuition
around life-producing gases,
detectable hints in terms of chemistry?
So interestingly enough, that entire question
relates to, I'm gonna say almost my life's work.
The work I'm doing now and the work I'm doing
for the next 20 years.
I wish I could give you a concrete number, like 1%. Like on the worst days, it's 1%. Let's say in my mind, you know, in the best
days, it's like 80%. And I could actually go into a lot of detail here, but I'll just give you the
simplest things. So first of all, we make an assumption that like us and our life here on Earth,
life uses chemistry. So we use chemistry because we eat food,
we breathe air, and we have metabolism that to break down food, to get energy, to store
energy, and then ultimately to use it. And all life here has some kind of byproduct in
doing all that, some kind of waste product that goes into the atmosphere. So I like to
think that life everywhere uses chemistry. Some people
have imagined like let's imagine like a windmill, like mechanical energy, just getting energy
and using it without storing it. And if there was life like that, it might not need to output a gas.
So we make this basic assumption of chemistry. That's the first thing. The second more complicated
thing that I and my team work on is what happens to the gas once it is produced by life. It goes into the atmosphere and a lot of gas is
just destroyed immediately actually by ultraviolet radiation or by oxygen. Oxygen is incredibly
destructive to a lot of gases. So the gas can be produced by life, but it could be just
completely destroyed by its environment. I guess we should pause on that, that you mentioned
your life's work. I mean, this is just the beautiful idea that it's kind of paralyzing when
you look out there and you wonder is there life out there? It's the first paralyzing.
Actually, before I encountered your work, I feel like an idiot. But, you know,
it feels like there's no tool to answer that question. And then what you kind of provided
is this cool idea that it might be possible to answer that by looking at the gases. I mean,
that's a really interesting, that's a beautiful idea. And, uh, yeah, so we could just pause on like, just that's
as a powerful tool, I think, that to build the intuition wrong, because I was totally
clueless about it. And that was kind of exciting. I mean, I'm sure there's a folks, I
probably early on in your life, who were very skeptical about this notion. Maybe I'm not sure, but generally, you would want to be skeptical.
It's like, well, all these kinds of other things could generate gases, all those things.
Oh, that's so true.
And that's a big part of this growing field is how to make sure that this gas isn't produced
by another effect.
I think that's...
I'm doing it, again, pausing on that and going back a bit. It's incredible to think,
but like, at least almost a hundred years ago, there's a record of someone
talking about the idea of a gas being an indicator of life elsewhere.
That idea was floating about. Yes, it was totally floating about.
And it comes down to oxygen, which on our planet fills our atmosphere
to 20% by volume.
And we rely on oxygen to breathe.
You know, when they hear about the people in Mount Everest running out of air, they're
really running out of oxygen.
Well, they're running out of oxygen because the air is getting thinner as they climb up
the mountain.
But without plants and bacteria, there's plants that bacteria that also photosynthesizes
and produces oxygen as a waste product.
Without those, we would have virtually no oxygen.
Our atmosphere would be devoid of oxygen.
So yeah, if your analyzed earth is oxygen, the strong indicator here.
Oxygen is a huge indicator.
And that's what we're hoping that there is an intelligence civilization, not too far
from here around a planet orbiting a nearby star with the kind of what we're hoping that there is an intelligence ofization, not too far from here around a planet orbiting
a nearby star with the kind of telescopes we're trying to build.
And they're looking back at our sun and they've seen our earth
and they see oxygen.
And they probably won't be like 100.0% sure
that there's life making it.
But if they go through all the possible scenarios,
they'll be left with a pretty strong hint
that there's life here.
Yeah. Okay, but how do you detect that type of gases that are on the planet from a distance? And that's going back to that. That's what people were skeptical about. When I
first started working on exoplanets, long time ago, people didn't believe we
would ever, ever, ever study an exoplanet atmosphere of any kind.
And now dozens of them are studied.
There's a whole field of people, hundreds of people working on exoplanet atmospheres, actually.
Wow.
But first there was a point where people didn't even know there's exoplanets, right?
When was the first exoplanet detected?
The first exoplanet around a sunlight star, anyway, was detected in the mid-1990s.
That was a big deal.
I kind of vaguely remember that.
Well, at the time, it was a big deal, but it was also incredibly controversial.
Because in exoplanets, we only had one example of a planetary system, our own solar system.
And in our solar system, Jupiter, our big massive planet, is really far from our star.
And this first exoplanet around a sunlight star was incredibly close is really far from our star.
And this first exoplanet around a sunlight star was incredibly close to its star.
It's star.
So close that people just couldn't believe it was a planet actually.
So maybe zoom out what the heck is an exoplanet?
An exoplanet is our name.
Like is the name that we call a planet orbiting a star other than our sun.
Right. Extrasolar, I guess is another.
You can call it extra solar.
Exoplanet is simpler.
But I think it's worth pausing to remember that each one of those stars out there in our
night sky is a sun.
Right.
And you know, our sun has planets, Mercury, Venus, Earth, Mars, etc.
And so for a long time, people have wondered, do those other stars or other suns have planets?
And they do.
And it appears that nearly every star has a planet, has a planet we call exoplanet.
And there are thousands of known exoplanets already.
So there's already, yeah, like there's so many things about space that it's hard to put
into one's brain because it starts filling it with awe. So yeah, if you visualize the fact that the stars
that we see in the sky aren't just stars,
they're like, they're suns.
And they very likely, as you're saying,
we'll have planets around them.
There's all these planets roaming about in this like dimly lit darkness with potentially
life.
I mean, it's just mind blowing, but maybe can you give a brief like history of discovering
all the exoplanets?
So there's no exoplanets in the 90s.
And then there's a lot of exoplanets now.
So how did that come about?
So many planets.
How did it come about?
Well, maybe another way to ask is,
what is the methodology that was used to discover them?
I can say that.
But I'd like to just say something else first,
where so exoplanets, the line between what is considered
completely crazy and what is considered mainstream research legit is constantly shifting?
This is awesome. Yeah, so before when I started an exoplanets it was still sketchy
Like it wasn't considered a career or a thing a place where you should be investing
Yeah, and right now now today it's so many people are working in this field a good
I don't know at least a thousand probably more. I don't know if that sounds like a lot to you, but it's a lot.
No, that's just a legitimate field of inquiry.
Yeah, legitimate field of inquiry. And what's helped us is everything that's helped
everyone else. It's software, it's computers, it's hardware. It's like our phones. You have
a fantastic detector in there. Like they didn't always have that. I don't know if you remember
the so-called olden days, we didn't have digital cameras.
We had film.
You take a film camera, you send the film away
and eventually it comes back and then you see your pictures
and they could all be horrible.
So yeah, it's, I mean, digital.
It just changed everything.
Data changed everything.
Yeah.
And so one thing that really helped exoplanets
were detectors that were very sensitive.
Because when we're looking for the
transiting planets, what we're doing is we're monitoring a star's brightness as a
function of time. It's like click, taking a picture of the stars every few seconds,
or minutes, and we're measuring the brightness of a star like every frame. And
we're looking for a drop in brightness that's characteristic of a planet going
in front of the star.
And then finishing it's so-called transit.
And to make that measurement, we have to have precise detectors.
And the detectors that are making the measurement, can you do it from Earth?
Is it, are they floating the ball in space?
Like what kind of telescope? Both. So on the ground, people are using telescopes, small telescopes that are almost just like a glorified
telephoto lens, and they're looking at big swaths of the sky.
And from the ground, people can find giant planets like the size of Jupiter.
So it's about 10 to 12 times the size of Earth.
We can find big planets, because we can reach about 1% precision.
So not sure how technical you you wanna get, but.
Well, yeah, how many pixels are we talking about?
Like what, you mentioned phones
is a bunch of megapixels, I think.
So for exoplanets, you wanna think about it as like
a pixel or less than a pixel.
We're not getting any information,
but to be more technical, our telescope,
you know, spreads the light out over many pixels, but we're
not getting information.
We're not tiling the planet with pixels.
It's just like a point of light, or in most cases, we don't even see the planet itself,
just the planet's effect on the star.
But another thing that really helped was computers, because transiting planets are actually
quite rare.
They don't all go in front of their star.
And so to find transiting planets, we look at a big part of the sky at once, or we look
at tens of thousands or hundreds of thousands, or even in some cases millions of stars at one time.
And so, you know, you're not going to do this by hand going through a million stars,
counting up the brightness. So we have computer software and computer code
that does the job for us and looks for a, you know, counts the brightness
and looks for a signal that could be due to a transiting planet.
And, you know, I just finished a job called Deputy Science Director for the MIT led NASA mission
test.
And it was my purview to make sure that we got the planet candidates, the transiting
light curves out to the community so people
could follow them up and figure out if they're actual planets or false positives.
So, so people could just, yeah, publish the data.
All the data scientists are darker, crunch and see if they can discover something.
They can discover something.
And in fact, the NASA policy for this mission is that all the data becomes public as soon
as possible.
So anyone can act.
It's not as easy as it sounds though to download the data and look for planets.
But there is a group called planethunterz.org.
And they take the data and they actually crowdsource it out to people to look for planets.
Yeah.
And they often find signals that our computers and our team missed.
So we mentioned exoplanets.
What about Earth- like or I don't
know what the right distinction is if is it habitable or is it earth like planets, what
are those different categories and how can we tell the difference and detect each?
Right, right. So we're not at earth like planets yet. All the planets we're finding are so
different from what we have in our solar system. They're just easier planets to find, but like in which way?
For example, there could be a Jupiter-sized planet
where an Earth should be.
We find planets that are the same size as Earth,
but are orbiting way closer to their star
than Mercury is to our Sun.
And they're so close that because close to a star
means they also orbit faster.
And some of these hot super earths we call them, their year, their time to go around their
star is less than a day.
And they're heated so much by their star, they're heated so much by the star, we think the
surface is hot enough to melt rock.
So instead of running out by the bay or the river, you'll have like liquid lava.
There will be liquid lava lakes on these planets, we think.
And life can't survive.
Way too hot.
Molecules for life would just be,
molecules needed for life just wouldn't,
wouldn't be able to survive those temperatures.
We have some other planets.
One of the most mysterious things out there,
factoid, if you will, is that the most common type
of planet we know about
so far is a planet that's in between Earth and Neptune size. It's two to three times the
size of Earth, and we have no solar system counterpart of that planet. That is like going
outside to the forest and finding some kind of creature or animal that just no one has
ever seen before, and then discovering that is the most common thing out there. And so we're not even sure what they are. We have a lot of thoughts as to
the different types of planet it could be, but people don't really know. I mean, what are your thoughts
about what it could be? Well, one thought, and this is more when we want to be rather than might be,
is that these so-called mini-Neptunes we call them, that they are water worlds, that they could be scaled
up versions of Jupiter's icy moons, such that they are planets that are made of more than
half of water by mass.
So, yeah, and what's the connection between water and life and the possibility of seeing
that from a gas perspective?
Okay, so all life on Earth needs liquid water.
And so there's been this idea in astronomy or astrobiology for a long time called follow
the water, find water, that will give you a chance of finding life.
But we could still zoom out, and the kind of the community can sense us is that we need
some kind of liquid for life to originate and to survive. Because molecules have to react.
You don't have a way that molecules
can interact with each other.
You can't really make anything.
And so when we think of all the liquids out there,
water is the most abundant liquid
in terms of planetary materials.
There really aren't that many liquids.
Like I mentioned liquid rock, way too hot for life.
We have some really cold liquids,
like almost gasoline, like ethane and methane
lakes that have been found on one of Saturn's moons, Titan. That's so cold though. And for exoplanets,
we can't study really cold planets because they're just simply too dark and too cold. So we usually,
so we usually are just left with looking for planets with liquid water. And to your point is, remember, as we talked about how planets are less
than a pixel in that way to say, so we can't see oceans on planet. We're not going to see
continents and oceans not yet anyway. But we can see gases in the atmosphere. And if
it's a small rocky planet, and this is going into some more detail, is a small, if we see
a small rocky planet with water vapor in the atmosphere,
we're pretty sure that means there has to be a liquid water reservoir.
Because it's not intuitive in any way, but water is broken up by ultraviolet radiation from the star
or from the sun. And on most planets, when water is broken up into H and O, the H, the hydrogen
will escape to space.
Because just like when you think of a child letting go of a helium filled balloon, it floats
upwards.
And hydrogen to light gas and will leave from Earth, leave from the planet.
So ultimately if you have water, unless there's an ocean, like a way to keep replenishing
water vapor in the atmosphere, that water vapor should be destroyed by ultraviolet radiation.
Got it, so there's a, okay, so there's a need for liquid.
I mean, I guess water,
well, is water sensors are the liquids?
I mean, the chemistry here is probably super complicated.
Well, there's not, it does,
but you know, there's not an infinite number of liquids.
There's maybe like five liquids
that can exist inside or on the surface of a planet.
And water is the one that exists for the largest range of temperatures and pressures.
And it's also the easiest type of planet for us to find and study is one with water vapor,
rather than a cold planet that has ethane and methane lakes.
What's your personal in terms of solar systems and planets that you're most hopeful about in terms of our closest
neighbors that you kind of have a sense that there might be somebody living over there,
whether it's bacteria or somebody that looks like us.
I'm hopeful that every star from nearby has a planet.
That's some life.
Because it almost has to for us to make progress.
We have to have that dream condition.
So the dream condition is like life is just super abundant out there.
Yeah, the dream, well, yes, the dream condition is that life is super abundant.
And it's based on the thought that if there is a planet with water
and continents, that it also has the ingredients for life.
And that the kind of base, the base, the base kernel thought is that if the ingredients for
life is their lifeful form, that's what we're holding on to.
With a relatively high probability.
Yes, that's it.
Okay, let's go into land of speculation.
What about intelligent life?
Us humans consider ourselves intelligent,
surprising me, or unsurprisingly,
do you think about, from your perspective
of looking at planets, from a gas composition perspective,
and in general, of how we might see intelligent life and your intuition about
whether that life is even out there.
Think the life is out there somewhere, the huge numbers of stars and planets.
I like to think that life had a chance to evolve to be intelligent.
I'm not convinced the life is anywhere near here, only because if it's hard for intelligent
life to evolve, then it will
be far away by definition.
Well, the sad thing is maybe from the artificial intelligence perspective is it makes me sad
there might be intelligent life out there that we're just not like the pathways of evolution
can go in all these different directions where we might not be able to communicate with it or even know that it or even detect its intelligence or even comprehend its intelligence
Yeah, convinced cats are more intelligence than humans that
That we're just not able to comprehend the
The measures the proper measures of their intelligence
My dog is so funny. He's a golden doodle his name's Leo
We joke that he's either a really dumb dog.
And sorry, he's not here to defend himself,
but he's either really dumb or he's a super genius,
just pretending to be dumb.
And he's possible.
He's he's a multi-dimensional projection of alien life here,
monitoring one of the, you know, one of the top scientists in the world
trying to find aliens just to make sure just to make sure that humans don't get
out of hand. It's funny. Oh, I'm definitely going to go in and ask him, ask him about that,
ask him about that one again. She's on to something. Yeah. What might we look for in terms of
signs of intelligent life? From your toolkit, do you think there are things that we should, we might be able to use
or maybe in the next couple of decades discover that would be different than life that's
like bacteria, that's primitive life?
I still love SETI, search for extraterrestrial intelligence.
I like to hope that if there is a civilization out there,
they're trying to send us a message.
I think, like, think about it.
I don't know, what are your thoughts?
Like, if you think about our Earth,
there's no structure we've built that intelligence
civilizations could see from far away.
There's literally nothing, not even the Great Wall of China.
And so to think like, why would this other civilization
build a giant structure that we could see?
Yeah, so it was said the ideas that we're both trying to hear signals and send signals, right?
Or we haven't sent one. They call that meti messaging. And there's a big kind of
fear over meti because you want to tell them you're here. It's kind of this like, let's wait till they
call us. Yeah. So we should be.
It's a dating game.
You have to, like, how many days do I wait before I call kind
of thing?
Yes, it is.
And so, but the funny thing is if no one sending us a message
of everybody's only listening, how do you make progress?
That's right.
And so, I mean, but there's also, there's the Voyager spacecraft.
We have these little pixels of robots flying out all over the place, some
of them like the Voyager reach out really far, and they have some stuff on them.
Okay, I just, I'm-
We do, we have the Voyager, but they're not really going anywhere in particular, and they're
moving very, very slowly on a cosmic scale.
Yeah, and when we say their far is kind of silly, because-
Yeah, it's all relative in astronomy. It's all relative. Yeah.
Yeah, I just, so from the, if you look at Earth from an alien perspective, from visually
and from gas composition, I wonder if it's possible to determine the degree of maybe productive
energy use.
I wonder if it's possible to tell like how busy these
earthlings are. Well, let's zoom out again and think about oxygen. So when
cyanobacteria arose like billions of years ago and figured out how to harness
the energy of the Sun for photosynthesis, they re-engineered the entire atmosphere.
20% of the atmosphere has oxygen now.
Like, that is a huge scale. They almost poisoned everything else by making this
what was apparently very poisonous to everything that was alive. But imagine, so are we doing
anything at that scale? Are we changing anything in like 20% of the earth with a giant structure
or 20% of this or 20% of that? Like, we aren't actually.
Yeah, that's humbling to think that we're not actually having that much of an impact.
I know.
Well, we are because in a way, we're destroying our entire planet, but it's humbling to
think that from far away, people probably can't even tell.
But from the perspective of the planet, when we say we're destroying global warming, all
that kind of stuff, what we really mean is we're destroying it for a bunch of different species including humans
But like I think the earth will be okay. Oh the earth will be the earth will remain
Whatever whatever happened to us the earth will still be here
And it'll still be difficult to detect any difference like it's sad to think that if humans destroy ourselves
any difference, like it's sad to think that if humans destroy ourselves, except potentially when you clear a war, it would be hard to tell that anything even happened.
Yeah, it would be hard to tell from far away that anything happened.
What about, what are your thoughts?
Now this is really really getting into speculation, Lander.
You've mentioned exoplanets were in the realm of, you know, this is beautiful edge between science and science
fiction, that some of us, a rare few are brave enough to walk, I think, in academia, you
were brave enough to do that. I think in some sense, artificial intelligence sometimes
walks that line a little bit. There is so much excitement about
excess terrestrial life and aliens in this world.
I mean, I don't know what,
how to comprehend that excitement,
but to me, it's great to see people curious
because to me, excess terrestrial life and aliens
is at the core a scientific question. and it's almost looks like people are
excited about science. They're excited by discovery. Discovery, right? And then the possibility that
there's alien life that visited Earth or is here on Earth now is is excitement about discovery
is excitement about discovery in your lifetime, essentially. What do you make of that?
There's recent events where DARPA or DOD released footage of these unmanned aerial phenomena
they're calling them now, UAP.
They got everybody super excited. Maybe there is like what what what's what's here on earth?
do you follow the
This world of people who are thinking about aliens that are already here or have visited I don't really follow what they follow me
I'd say because in this field if you're a scientist of any kind you get
Because in this field, if you're a scientist of any kind, do you get the people contact us?
Me.
There's a lot of them about, hey, I have stuff you should see.
Hey, the aliens are already here.
I need to tell you about it.
And I know there are people out there who really believe.
There's a psychology to it.
There's a psychology to it.
And it's fascinating.
But OK, so the similar to artificial intelligence.
But I still, but like you, I'm still enamored
with the point that it is out there.
And that people believe so strongly.
And that's so many people out there believe.
Believe and I don't know, I, I, I, I, I,
I'm not as allergic to it as some scientists are
because ultimately if aliens showed up or do show up
or have showed up,
these are going to be very difficult to study scientific phenomena.
In fact, going back to cats and dogs,
I think we should be more open-minded about developing new tools
and looking for intelligent life on earth that we haven't yet
found, or even understanding the nature of our own intelligence, because it kind of
is an alien life form, the thing that's living in our skull.
It's so true, when we don't understand consciousness.
Yeah.
It's true.
We don't understand how biology's hard, unpacking it and working it all out, it's a stretch.
And they say, too, that our thinking mind is like the tip of a pyramid, that everything
else is happening under the hood, but what is happening?
But the thing with, so the typical scientist response to, you know, are there aliens here,
is that we need to see major evidence, Not like a sketchy picture of something,
we need some cold hard evidence
and we just don't have that.
That's exactly right.
But from my perspective,
I admire people that dream.
And I think that's beautiful.
The thing I don't like, there's two sides of the folks
that probably listen to this podcast is,
oh, those that dream, I think, is beautiful,
that wander what's out there, what's here on earth.
And then the other ones who are very conspiratorial
in thinking that stuff is being hidden.
And big thumbs about institutions.
Right, right, right.
Okay, I have a funny thing to talk about that.
So one of my colleagues had a really good answer to that.
And it's not me saying this, so I can say this.
But he said, look, he works with NASA, not at NASA.
He works with government, not in the government.
It's kind of me, but he'd say, trust me,
they couldn't hide it if they tried.
Do you know what I'm saying?
Like, everybody, I know.
We're not smart enough, we're good enough.
We're not we, or not me, or not you,
but whoever to cover it up, it's sort of a myth.
not me or not you, but whoever to cover it up, it's just, it's sort of a myth. Yeah. It makes it sad because the people at NASA, the people at MIT, the people in academia,
the people in these institutions, and yes, even in government are often trying, they're
like just curious descendants of apes. They just, they. They want to do good, they want to discover stuff,
they're not trying to hide stuff.
In fact, most of them, in terms of leaks,
would love to discover this and release this kind of stuff.
I...
Did you ever watch this show called The X-Files?
Yeah.
Scully and Molder.
Yeah.
And what I love, actually, I used to put it up
during my talks, my public talks.
There's a picture of a UFO or what looks like UFO and it says, I want to believe.
So that's where I think a lot of us are coming from.
I want to believe.
And it's so great in one time, I put that up and this very, very nice couple approached
me really nervous afterwards.
And I said, hey, can we take you out for lunch sometime? And I said, Sure. And they were like the nicest
people. And just one of many who has an alien, alien abduction story. And the woman could
never have kids. They were older, but they didn't have kids, which for them was a real
source of regret. But it was because the aliens who abducted her had made it so that she
couldn't have kids. And she had apparently something implanted behind her ear, which was somehow unimplanted later.
And they're just so sincere. And they're such a lovely couple. And they just wanted to share
their story. That's a real, whatever that is, that's the real thing, the mystery of the human mind.
Right. Is more powerful than any alien or I mean it's
as interesting I think as the universe and I think there's somehow
intricately linked. Maybe getting a sense of numbers, how many stars are there in
maybe I don't know what the radius that's reasonable to think about. I don't know if the observable universe is like way too big to think about.
But in terms of when we think about how many habitable planets there are,
what are the numbers we're working with in your sense?
What are the scale?
Honestly, the numbers are probably like billions of trillions of stars.
Yeah, you know, in the UK, I think I don't know if we do that here,
but they will call a billion trillion. We put like one billion followed by a trillion.
Yeah, it's kind of weird, but here, I don't even know how to say the number 10 to the
20. Like, if you know what that is, that's one followed by 20 zeros. That's a big number.
And we don't have a name for that number. There's so many.
Per star, I think we kind of mentioned this. Is there a good sense? There's probably
argument about this, but per star, how many planets are there?
Is there?
We don't have that number yet, per se.
We're not really there.
But some people think that there's many planets per star.
There's this analogy of filling the coffee cup.
You don't usually just pour one drop.
You fill it.
And that planetary systems, we see stars being born
that have a disc of gas and dust,
and that ultimately forms planets.
So the idea, this kind of concept is that planets,
so many planets form too many,
and eventually some get kicked out
and you're left with like a full planetary system,
a dynamically full system.
And so there have to be a lot,
because so many form and a bunch survive.
That, I mean, that makes perfect intuitive sense, right? Like, why would that happen? a dynamically full system. And so there have to be a lot, because so many form and a bunch survive.
That, I mean, that makes perfect
in two to the sense, right?
Like, why would that happen?
Right.
Well, there's other thoughts too though.
These big planets that are really close to the star,
we think they formed far away from the star
where there's enough material to form,
and they migrated inwards.
And some of these planets migrating inwards
due to interaction with other planets
or with the disc itself, they may have cleared it out,
like kicked other planets out of the system.
So there's a lot of ideas floating around.
We're not entirely sure.
And what about Earth-like planets?
Is that that's another level of uncertainty that?
It's the level of uncertainty.
If we think of an Earth-like planet being an Earth around a sun in the same orbit. An Earth-like planet being an Earth-sized planet
in an Earth-like orbit about a sun like star. We're not there yet. We're not able to detect
enough of those to give you a hard number. Some people have extrapolated and they will say as many
as one in five stars like our sun could be hosting a true earth like planet on the topic of space exploration.
There's been a lot of exciting developments with NASA with space X with other companies.
Successfully getting rockets into space with humans and getting them to land back especially with space X.
with humans and getting them to land back, especially with SpaceX.
What are your thoughts about Elon Musk and SpaceX,
Crew Dragon, while working with NASA to launch astronauts?
What's your sense about these exciting new developments?
Well, SpaceX and other so-called commercial companies
are only good news for my field,
because they're lowering the cost of getting to space.
By having reusable rockets, it's just been, it's incredible. And we need cheaper access to space.
So from a very practical viewpoint, it's all good. About getting people, there's this dream that we
have to go to Mars, boots on Mars. What do you think about that? You mentioned probes. What's the value of humans?
Is that interesting to you from both scientific and a human perspective?
Human mostly, I think it's such in our desire to explore,
because part of what it means to be human.
So wanting to go to another planet
and be able to live there for some time,
it's just what it means to be human.
You know, oftentimes in science and engineering,
big, huge discoveries are made when we didn't intend to.
So often this kind of pure exploratory type of research
or this pure exploration research
can lead to something really important.
Like the laser, we couldn't really live without that now.
At the grocery, you scan your foods,
there's surgery that involves lasers.
GPS, we all use our GPS.
We don't have GPS because someone thought, hey, it would be great to have an navigation
system.
And so I do support, I do, I just, but I really think it comes primarily just from the desire
to explore.
Do you think something, there's a lot of criticism and a lot of excitement about Mars?
Do you think there's value in trying to go
to put humans at Mars, first of all,
and second of all, colonize Mars?
Do you think there's something interesting
that might come from there?
I'm convinced there will be something interesting,
and I just don't know what it is yet.
But I don't think having some commercial value
or value in the metric of something useful
is really what's motivating us.
So really, you see exploration is a long-term investment into something awesome that eventually will be commercial value.
I do actually.
So what about visiting...
Okay, I apologize, but I mean there's an exciting longing to visit Earth-like planets elsewhere.
So what's the closest Earth-like planet you think is worth visiting and how hard is it?
Wow, it is very hard.
I mean, our nearest, called Earth-mass planet, it's orbiting a star very different from
our own Sun, an M-dore star, a small red star, proximate centauri. It's over four light years away. And we can't travel
at the speed of light. We can't even try, I mean, it would take tens of thousands of years to get
there with conventional methods. So you know the movies like multi-generally, yeah, this movie
passenger, have you seen that movie? Passinger. It's about a big space ship that is traveling to another planet and everyone's hibernating.
I won't give you the spoiler alert because one person wakes up and then it's kind of a
problem.
Okay.
Got it.
But yeah, the multi-generational ships, I mean, when you think about where we're headed
as a species, maybe we don't send people.
Maybe we end up sending raw biological materials and instructions to print out humans.
It sounds kind of far-fetched, but already we're printing like liver cells in the lab and
beating heart cells. We're starting to reconstruct body parts. I mean, the thing is it is so hard
to get to another planet that this thought of printing humans or printing life forms actually could be easier.
Yeah, that's somehow so sad to think of the idea that we would launch a successful spaceship
that has multi-generational like non-human life.
And it's going to reach other intelligent life.
And by the time they figure out where it came from human
civilization would be extinct.
Wow, yeah, that is really.
I mean, that's so that's one. There's a there's a there's a tempting thing to think about.
What are the possible trajectories? So, you know, Elon keeps talking about multi planetary
us becoming multi planetary species.
I mean, sure, Mars is a part of that,
but like the dream is to really expand outside
the solar system.
And it's not clear, just like it, as you said,
like what the actual scientific engineering steps
that are required to take, it seems like so daunting,
so daunting. So like. So like, the smart thing
seems to be to do the most achievable near daunting task, even if there doesn't seem to be
a commercial application, which I think is colonizing Mars. But like, from your perspective,
is there some Manhattan project style, huge project in space that we might want to take
on?
And you've had roles, you've had scientists hat roles, and then you also had roles in terms
of being on committees and stuff, determining where funding goes and so on.
So is there a huge multi trillion we've been throwing the T-word around,
certainly a lot, but these huge projects that we might want to take on?
Well, first of all, we want to find the planets like Earth first.
Like, just even finding those Earth-like planets is a billion dollar endeavor,
billions of dollars endeavor. And that's so hard because an Earth is so small, so less massive,
and so faint compared to our Sun. It's the proverbial
needle in a hay sack, but worse. And we need very sophisticated space-based telescopes to
be able to find these planets and to look at them and see which ones have water and which
ones have signs of life on them.
Yeah, the star-shade project that you're part of.
Star-shade.
Star-shade, yeah, this probably was bad as thing over the scene.
Right. You know what's interesting?
You need to discover what it is.
Starshade. So what's amazing about Starshade is it was first conceived of in the 1960s.
Imagine that and revisit it every decade until now when we think we can actually build it.
And Starshade is a giant, specially shaped screen. It is about, there's different versions of it,
but think about 30 meters in diameter. So you're blocking out the sun.
You're effectively blocking out the star.
Yeah.
So that you can see the planet directly and starshade would have a spacecraft
attached to it and it would fly in space far away from Earth's gravity.
And it would have to formation fly with a space telescope.
So the idea is that starshade blocks out the starlight in a very careful way.
And it has to block that starlight out so that the planet that is 10 billion times fanger than
the star that only the planet light goes to the telescope.
Yeah, so information, meaning the telescope flies in, you've got a presentation on this,
but like it would fly like in and This is extremely high precision endeavor. Yeah, we had this analogy like asking a friend to hold up a dime five miles away
Perfectly like at the perfect line of sight with you
And the shape of it is pretty cool. I mean
I don't know exactly what the physics of that like what the optics are that require that shape
I can tell you it turns out that if you block out a star,
imagine blocking out a star with a circle circularly or a square shape screen,
you wouldn't actually be blocking it because the star acts like a wave,
the star light can act like a wave, and it would actually bend around the edges of the screen.
And so instead of blocking out the light, you're expecting to see nothing, you would see ripples.
And the analogy that I love to give, it's like throwing a pebble in a pond.
You know, you get those ripples, you get these concentric ripples and they go out.
And light would do something quite similar.
You'd actually see ripples of light.
And those ripples of light, they're actually way brighter than the planet we'd be looking
for.
So.
So they would introduce this noise noise. Yeah, noise. And so this star shade, it's like a
mathematical solution to the problem of diffraction, it's called. And this
is what the first person who thought about star shade in the 1960s worked out,
the mathematical shape, or one solution, one family of solutions. And the
idea is that when the star shade, this very special shape, like a giant flower,
with petals, when it blocks out the light, the light bends around the edges, but interacts with itself in a way to give you a very, very dark image. It would be like throwing a pebble in a
pond. Instead of getting ripples, the pond would be perfectly smooth, like incredibly smooths
to one part in 10 billion, and all the waves would be on the outer edges, far away from where you drop that pedal,
Pebble.
And so this camera would be able to, oh, this camera, this does go, would be able to get
some signal from the planet then.
Yes, and it would be hard because the planet is so faint.
But with the star out of the way, the glare of that bright, bright, bright star, with that
out of the way, then it becomes a much more manageable task.
So, how do we get that thing out there? We're still working with unlimited money.
Okay, we're moving on limited money. We have some more engineering problems to solve, but
not too many more. We've been burning down our so-called tall pull list.
And we just...
What kind of list?
We call it, technology, tall pull. It's the phrase where you have to figure out what are your hardest problems and then
break those down to solve.
So the star shade, one of the really hard problems was how to formation fly at tens of
thousands of kilometers.
It's like, wow, that is insane.
And the team broke that down actually into a sensing problem because of the star shade,
how do you see the star shade precisely enough to control it?
Because if you're shining a flashlight,
you know the beam spreads out.
So the star shade has a beacon, an LED or a laser,
it's gonna spread out so much
by the time it gets to the telescope.
The problem wasn't how do you tell the star shade
how to move around fast enough to stay in a straight line.
The problem was how are you able to sense it well enough?
So problems like that were broken down and money that came from NASA to solve problems
is put towards solving it. So we're, we've got through most of the hard problems right
now. Another one was that star shade, even though it's looking at a star, light from our
own sun, could hit the edges of the star shade and bounce off into the telescope, believe
it or not.
And that would actually ruin it because we're trying to see this tiny, tiny signal.
So then the question is, how do you make a razor thin edge?
Those pedal edges would be like, have to be like a razor.
What materials can you?
So there's a series of problems like that.
So there's a materials problem in there.
Some of them, materials problem.
And there's one.
So we almost finished solving all those problems.
And then it's just a matter of building one and testing it
in a full-scale-sized facility.
And then building the telescope is just a matter of time
to build everything and get it up for launch.
So this is an engineering project.
It's a real engineering project. I actually can tell you about two other projects that are not mine.
I like to call star shade mine because it was my project that I helped make it mainstream.
Without line is constantly shifting. When I started, when I got this leadership role on star shade,
I remember telling people about it. And it was definitely not on the mainstream okay line.
It was on the giggle factor side of the line. And people would just laugh like
that's dead. Like you can never formation fly. Or they'd say, why are you working on
that? That's just so not it's not so awesome. There's a there's a few things you've done
in your life. And that's when I first saw star shade. I was like, what? Really? And
then like it sinks in. I mean, it's the same thing I felt with Elon Musk
or certain people who do crazy stuff.
And then they actually make it work.
I mean, if you get star-shaped information
flying together, and how awesome is that?
If you actually make that happen,
even from a robot, I'm sorry,
from the robotics perspective, even if from a robot, I'm sorry, from the robotics
perspective, even if it doesn't give us good data, that's just like a cool thing to get out there.
I mean, it's really exciting. Really cool. So there's two other topics that aren't mine,
but I still love them. Yeah. One of them, let's just talk about it briefly, because it's not a pro,
but it's the idea to send a telescope very far away to 500 times the earth's sun distance.
And this is way farther than the Voyager spacecrafts
are right now.
And to use our sun as a gravitational lens,
to use our sun to magnify something that's behind it.
It's gotta sink in for a minute.
Yeah, exactly.
I mean, I don't know what the physics of that is.
Like how do you use the sun?
In astronomy, and Einstein thought about this initially,
we can use a massive object, Ben space.
And so light that should be traveling like straight.
It actually travels around the worked space.
And somehow you figure out a way to use that
from magnification.
You have a way to use that from magnification, that's right.
There are galaxies that are lens,
so-called gravitational lens, by intervening galaxy clusters, actually. And there are micro-lensing
events where stars get magnified as an unseen gravitational lens star passes in between us
and that very distant star. It's actually a real tool in astronomy, using gravitational lens
to magnify, because it bends more rays towards you than
normally would, you'd normally see. And again, we're trying to get
more higher resolution images that are basically boiled down to
light. Well, it boils down to light. And then you can maybe get
more information about. Well, in this case, you would ask me,
let's say, if this thing could get built, it would
take something like they like to say 25 years to get from here to there, 25 years, and then
it could send some information back to us.
And then you'd say, so Sarah, how many pixels?
And I wouldn't say one or less than one.
I'd say, you know, it could be like 10 by 10 pixels.
It could be 100 pixels, which would be awesome.
I mean, that's still crazy that we can get a lot of information from that.
Crazy, right? And it's crazy for a lot of other reasons because again, you have to line up the
sun and your target. You only have one telescope per target because every star is behind the sun in a
different way. So it's a lot of complicated things. What about the second one? The second one, it's called star shot.
Star shot means like big dreams.
And it's initiative by the Breakthrough Foundation.
And star shot is a concept to send thousands of little tiny
spacecraft, which they now call star chip.
So instead of star ship, it's star chip.
And there's a little chip. And the star chip. So instead of star ship, it's star chip. And there's a little chip. And
the star chip. So like sending like thousands of little turtles being born, they're not
all going to make it. Because they use to send lots of them. And each of these star chips,
once they're launched into, I guess, low earth orbit, they will deploy a solar sail.
That's a few meters in diameter. And they'd use it on Earth.
We would have a bank of... This one is still a bit on the other side of the line, but we'd have a bank
of telescopes with lasers. They'll be like a gigawatt power. And these lasers would momentarily shine
upwards and accelerate. They'd hit these sails.
They'd be like a power source for the sale.
And would accelerate the sales to travel
at about a 20th of the speed of light.
Is that as crazy as this sounds?
Well, like any good engineering project,
it has to be broken down into the crazy parts.
And the breakthrough initiative,
like to their huge credit, is sponsoring,
getting over these, actually,
they've listed, initially they listed 19 challenges.
This is broken down to concrete things.
Like one of them is, well, you have to buy the land
and make sure the airspace is okay
with you sending up that much power overhead.
Another one is you have to have material on the sale
where the lasers won't
just vaporize it. So there's a lot of issues. But anyway, these sails would be accelerated
to 20th speed of light. And their journey to the nearest star would now, wouldn't, would
no longer be tens of thousands of years, but could be 20 years. Okay, 20. So it's not,
not as bad as tens of thousands. Yeah. essence. And these thousands or whatever however many make it,
they'll go by the nearest star system
and snap some images and radio the information back to Earth.
Those are traveling so fast they can't slow down,
but they'll zoom by, take some photos, send it back.
I read.
But see, just what I want you to pause on for a second
is that just by making that a real concept
and the money given won't make it happen, but what is done is it's planted the seed.
And it's shifted that line from what is crazy to what is a real project.
It's shifted it just ever so slightly enough, I think, to plant the seed that we have to
find a way to somehow find a way to get there.
That is, again, to stay on that.
That is so powerful.
Take a big big crazy idea and
Break it down into smaller crazy ideas ordered in a list and
Knock it out one of the time
I don't know I've never heard anything more inspiring from an engineering perspective because that's how you solve the impossible things
so you open your new book,
discussing Rogue Planet PSO J318, I never said this out loud, 0.522. So a Rogue Planet,
which is just this poetic, beautiful vision of a planet that, as you write, lurches across the galaxy, like a rudderless ship wrapped in perpetual darkness.
It's surface swept by constant storms,
as black skies raining mold and iron.
Just like the vision of that, the scary, the darkness,
just how not pleasant it is for human life, just the intensity of that metaphor, I don't
know.
And the reason you use that is to paint a feeling of loneliness and despair.
And why maybe on the planet side, why does it feel maybe it's just me?
Why does it feel so profoundly lonely on that kind of planet?
Like what?
I think it's because we all want to be a part of something, a part of a family,
or a part of a community, or a part of something. And part of a family or a part of a community or a part of something.
And so our solar system, and by the way, I only, it's sort of like a, like when you treat
yourself to like eating an entire tub of ice cream, like I sometimes treat myself to imagine
things like this and not just be so cut and dried. But when you imagine that this planet
is not, because I don't want to give emotions to a planet per se,
but the planet's not part of anything.
It's somehow probably, it's just all on its own,
just kind of out there, without that warm energy from its sun.
It's just all alone out there.
To me, it was this little discovery
that I actually feel pretty good at being part of this solar system.
It felt like we have a sun, we have like a little family.
And it felt like it sucked for the rogue planet
to just floating about, not floating,
of flying rudderless.
By the way, how many rogue planets are there in your sun?
We don't know totally.
I mean, there are some rogue planets that are just born on their own.
I know that sounds really weird to be.
How can you be born in orphan?
But they just are.
Because most planets are born out of a disc of gas and dust around a star.
But some of these small planets are like totally failed stars.
They're so failed, they're just small planets on their own.
But we think that there's probably, honestly, there's another path to a rogue planet. That's one that's been kicked out of its star system by other planets,
like the game of billiard balls. That means it just gets kicked out. We actually think there's
probably as many rogue planets as stars. No flying out there, fundamentally alone. So the book
mentally alone. So the book is a memoir, is about your life and it weaves both your fascination with planets outside the solar system and the path of your life
and you lost your husband which is a kind of central part of the book that created a feeling
of the rogue planet. By the way, what's the name of the book?
The name of the book is the smallest lights in the universe.
What's up with the title? What's the meaning?
The title has a double meaning. On the face of it, it's the search for other earths. Earths are so dim compared to the big, bright, massive star beside them.
Searching for the earths is like searching for the smallest lights in the universe.
That has this other meaning too. I really hope that you or the other people listening never get to the place where you're just, you
fall off the cliff into this horrible place of huge despair. And once and a while you get
a glimmer of a better life of some kind of hope. And those are also the small slides in
the universe.
Well, maybe we can tell the full story before we talk about the glimmer of hope.
What did it feel like to first find out that your husband, Michael Sik?
It was incredibly frustrating.
Like lots of us have had some kind of problem that the doctors completely ignore.
Just that they kept blowing him off.
It's nothing.
Gar they paid to just say it's nothing?
I mean, it's just insane.
It was just so angry.
And we finally got to a point where he was really sick.
He was like in bed, not able to move basically.
And it turned out all the things they ignored
and not done any tests.
He had like a 100% blockage in his intestine, like 100%
like nothing could get out, nothing could get in.
And it was pretty, pretty shocking to even hear them that it could be nothing.
What was the progression of it in the context of the maybe the medical system of the doctors?
And what did feel like, did you feel like a human being?
I felt like a child, like the doctors were trying to
water down the real diagnosis or treat us like we couldn't know the truth or they didn't know. You know, I felt mixed like it's not a good situation. If you think
the doctor either has no idea what he or she is doing, or if the doctor is purposely, let's just say lying to you to sugar code it.
I didn't know which one of it was, but I knew it was one of those.
What were the things you were suffering for?
Well, initially he just had a random stomachache.
I hate to say that out loud because I know a lot of people will have a random stomachache.
Yeah.
But so he just had a bad stomachache and then, hmm, this is weird.
A few days later, another bad stomachache kind of gets worse. Might go away for a few weeks,
might come back. And at the time, all I knew was my dad had had that same thing.
Not the same identical system, but he had these really weird pains and he ended up having the worst
diagnosis. One of the worst diagnoses you can get from a random stomachache is pancreatic cancer.
Because the time, the pancreas, but you can't feel anything, so by the time you feel pain,
it's too late, it's spread already.
So I was just like beside myself, I'm like, this is like, wow, this guy, he's a random
stomachache.
All I know is another man I loved had a random stomachache and it didn't end well.
How did you deal with it emotionally, psychologically, intellectually as a scientist?
What was that like, that whole, because it's not immediate, it's a long journey.
It's a long journey and you don't know where the diagnosis is going.
So anyone who's suffered from a major illness, there's like always branches in the road.
So you know, he had this intestinal blockage.
I can't imagine someone in their 40s
having that and that being normal. But the doctor is like, it could be nothing.
It could just cut it out. You don't need most of your intestine. It's a repeating pattern.
Just cut that out. It could be fine. But it ended up not being fine and he was diagnosed as being
term-leal. Well, it really changed my life in a huge way. First of all, I remember immediately
one summer, the summer when this
happened, I started asking everyone I knew. I would ask you, I don't know, smart, my job
to put you on the spot, I'd say, you have one year of live or two or three. What will
you do differently about your life now? Lex, you have one year to live. What would you
do? I mean, it's hard. I don't know if you want to answer that.
No, no, no, I think about it a lot. I mean, that's a really good thing to meditate on. We
can talk about maybe how, why you bring that up, what if it is or not a heavy question,
but I get, I think about mortality a lot. And for me me it feels like a really good way to focus in on is what you're doing today.
The people you have around you, the family you have, is it...
Does it bring you joy? Does it bring you fulfillment. And basically, for me,
a long ago, try to be ready to die any day. So like today, you know, I kind of
woke up, look if I was nervous about talking to you, I've really admired your work.
And the book is very good and it's a super exciting topic.
But then, you know, there's this also feeling like, if this is the last conversation I have
in my life, you know, if I die today, will this be, will this be the right?
I get my glad today happened and it is and I am glad today happened.
So that's the way.
And that's so unique.
I never got that answer from a single person.
The busyness of life, there's goals, there's dreams, there's like planning, planning.
And various few people make it happen.
That's what I learned.
And so a lot of these people, like you run out of time.
It's not so much you run out of time,
but I'd come back later and be like,
okay, why don't you do that?
And if that's what you would do,
if you're gonna die a year from now,
why don't you make it real?
Simple things, spend more time with family.
Like why don't you do that?
And no one had an answer, it turns out,
unless you usually, unless you have,
you really do have a pressing end of life.
People don't do their bucket list
or try to change their career. And some people can't, so we can't, like for a lot of people,
they can't do anything about it. And that's fine. But the ones who can take action for
some reason never do. And that was one of the ways that Mike's death or at the time his
impending death really, really affected me. Because you know, for these sick people, what
I learned, he had a bucket list and he was
able to do some of the bucket list.
It was awesome.
But he got sick pretty quickly.
So if you do only have a year to live, it's ironic because you can't do the things you
wanted to do because you get too sick too fast.
What were the bucket list things for you that you realized like, what am I doing with my
life?
That was the major cons of him after he died, I didn't know.
Like I was just lost because when something that profound happens, all the things I was
doing, most of the things I was doing were just meaningless.
Was so tough to find an answer for that.
And that's when I settled on, I'm going to devote the rest of my life to trying to find
another earth and to find out to find that we're not alone.
What is that longing for connection with others?
What's that about?
What do you think?
Why is that so full of meaning?
I don't know why.
I mean, I think it's how we're hardwired.
Like, one of my friends some time ago,
actually, my dad died.
He never heard someone say this before,
but he's like, Sarah, you know,
why are we evolved to take death so harshly?
Like, what kind of society would we be
if we just didn't care people died?
That would be a very different type of world.
How would we as a species have got to where we are?
So I think that is tied hand in hand
with why do we see connection?
It's just that what we were talking about before,
that subconsciousness that we don't understand.
Yeah, couple, the other side,
the flip side of the coin of connection and love
is a fear of loss.
It's like that was, again, I don't know, it's so it makes you appreciate the moment, is that the thing ends.
Yeah, that's definitely a hard one. The thing ends, but...
What?
And it's hard to not, you wouldn't want to limit. Like it's...
Like my dog who I love so much, I'll start to cry.
Like I can't think about the end. I know he'll age much faster than I will.
And someday it will end, right? But it's too sad to think of. But should I not have got a dog?
Right. Should I have not brought this sort of joy into my life because I know it won't be forever.
It's... Well, there's a philosopher and his becker who wrote a book, Denal of Death, and just
and warm of the cores.
And as another book talks about terror management theory, Sheldon Solomon, I just talked
them a few weeks ago.
There's a brilliant philosopher, a psychologist, that their theory, whatever you make of it,
is that the fear of death is at the core of everything
we do. So like, you're, that you think you don't think about the mortality of your dog,
but you do. And that's what makes the experience rich. Like there's this kind of, like in the
shadows, looks, the knowledge that this won't last forever and that
makes every moment just special in some kind of weird way that the moments are special
for us humans.
I mean, sorry to use romantic terms like love, but what did you learn about love from losing
it from losing your husband?
Well I learned to love the things I have more.
I learned to love the people that I have more and to not let the little things bother me as much.
What about rediscovery or like the discovery of the little lights in the darkness? So, the book, I think you brilliantly described the dark parts of your journey.
But maybe can you talk about how you were able to discover the lights?
They came in many ways, and the way you like to think about it is like grief is an ocean. You know, it's tiny islands of the little,
like the little lights and eventually that ocean
gets smaller and smaller and the islands
like become continents with lakes.
So initially it'd be like the children laughing one day
or my colleagues at work who rallied around me
and would take me away from my darkness
to work on a project.
Later on, it turned out to be a group of women, my age,
all widows, all with children in my town.
And it would be, even though it was a bit more roast getting together,
still very joyful at the same time.
What was the journey of rediscovering love like for you?
So refinding. I mean, is there some by way
of advice or insight about how to, how to rediscover the beauty of life?
Of life. It's a hard one. I think you just have to stay open to being positive and just
to get out there.
Do you still think about your own mortality?
You mentioned that that was a thing that you would meditate on as a question
when it was right there in front of you, but do you still think about it?
I think I will after talking to you.
But no, it's not really something I think about.
I mean, I do think about the search for another earth
and will I get there?
Will I be able to conclude?
My search and is there one?
I guess time goes by, that window to solve that problem
gets smaller.
What would bring you, again, I apologize if this makes concrete the fact that life is
finite, but what what would bring you joy if we discovered while you're still here?
We'll bring me joy finding another earth and earth like planet around a sun-like star,
knowing that there's at least one or more out there, being able to see water that it has signs of water and being able to see some gases that don't belong.
So I know that the search will continue after I'm gone, enough to fuel the next generation.
So just like opening the door and there's like this glimmer of hope.
What do you think it will take to realize that?
I mean, we've talked about all these interesting projects,
Star Shade especially, but is there something that you're
particularly kind of hopeful about in the next 10, 20 years
that might give us that exact glimmer of hope
that there's earth-like planets out there?
I stand behind Star Shade in all cases.
But there is this other kind of field that I that everyone is involved in because starshade is hard. Earth star hard.
But there are there's another category of planet star type that's easier and these are planets orbiting small red dwarf stars. They're not earth like at all think like Earth cousin instead of Earth twin.
They're not earth-like at all, think like earth cousin instead of earth twin.
But there's a chance that we might establish that some of those have water and signs of life on them.
That's near a term that's star-shade and we're all working hard on that too.
Let me ask by way of recommendations, I think a lot of people are curious about this kind of stuff. What three books, technical or fiction or philosophical or anything really had an impact on your life and or you would
recommend, besides of course your book. There's one book I wish everyone could read. I'm not
sure if you've read it. It's actually a children's book like a young adult book. It's called The Giver.
Yes. I...
And it is the book that kids in school read now. And I
leave. Sorry. That's a not that's wow.
Except. Sorry, that that called me off guard. So when I first came to this
country, I didn't speak much. It's really what made me.
I had a profound impact on my life. And I'm at a really important moment
because they give it to kids. Like I think
I it'll school I think or maybe something like that. I'm so surprised you've even heard of this
book. Yeah, so they give it, but like it's the value of giving the right book to a person at the
right time. Wow. I was, because it's very accessible. Do we want to share what the story is without
spoiling it? Oh, yeah, you can without spoiling, right?
It's, yeah.
Well, it follows this boy in this very utopic society that's like perfect.
It's been all clean cut and made perfect, actually.
And as he kind of comes of age, he starts realizing something's wrong with his world.
And so it's part of that question, are we going to evolve as, I mean, this isn't what's
there, but it made me wonder, you know, are we evolving to a better place?
Is there a day when we can eliminate, you know, poverty and hunger
and crime and sickness in this book? They pretty much have in a society that the boys
in and sort of follows him. And he becomes a chosen one to be like a receiver, the givers
the old wise man who retains some of the harshness of the outside world so that he can advise
the people. As the sort of boy comes of age andness of the outside world so that he can advise the people.
And as a sort of boy comes of age and is chosen for the special role, he finds the world
isn't what he expects.
And I don't know about you, but it was so profound for me because it jolts you out of reality.
It's like, oh my God, what am I doing here?
I'm just going with the flow with my society.
How do I think outside the box and the confines of my society, which surely carries negative
things with it that we don't realize today?
Yeah, and also in the flip side of that is,
if you do take a step outside the box on occasion,
what's the psychological burden of that?
Like, is that, is that a step you wanna take?
Is that a journey you wanna take?
What is that life like?
I don't know, I felt like from the book,
you have to take it. I found from the book. I never thought, like, now that you're to take, what is that life like? I don't know. I felt like from the book, you have to take it. I found from the book.
I never thought like, now that you're saying it, I see what you're saying.
The burden is huge, but I always felt like the answer is yes.
You absolutely want to know what's outside. But you can't do that.
If you're very, it's hard to be objective about your own reality.
Yeah. I think it's a very human instinct, but it also,
the book kind of shows that it has an effect on you.
And it's a really interesting question about our society and taking a step out.
It's by Lois Lowry, I think, is Hibernation. I really do hope everyone created it.
And it is a young adult book, but it's still incredibly, I'm really glad, I only read it because
my kids got it for school. I just thought, okay, well, I don't know,
I just see what this is about, and I just, wow.
Yeah, I think it's also the value of education.
I think, I'm surprised you mentioned,
I've never really mentioned to anybody.
I'm sure a lot of people had some experience like me
and maybe.
It's a generational thing, though,
because the book came out, I think, in the 90s,
so if you're older than me, that book didn't exist when we were in middle school
So I just do think a lot of people won't have heard of it. But it's an interesting question of like those books
I
Mean I'm reminded often as opposed to seems true. There's a lot of subjects but books are special
It thought at early age like middle school maybe early high school, those can change the direction
of your life. And also certainly teachers, they can change completely the direction of
life. There's so many stories about teachers of mathematics, teachers of physics, of
all, and you kind of subjects basically changing the direction of a human's life. That's like not to get on the whole almost like a political thing, but you know,
we undervalue teachers. It's a special, it's a special position that they hold.
That's so true. Yeah. Well, I do have two other books or two other things. One is something I came across just a few days ago actually.
It's actually a film called Picture a Scientist.
And when you picture a scientist, you probably don't picture the
women and women of color in this film.
And it is a way to get outside your box.
I really think everyone interested in science, just peripherally should watch this because it is shocking and sobering at the same time.
And it talks about how, well, I think one of the messages across is, you know, we really
are like, I don't know if we're hardwired to just like people like ourselves, but we're
excluding a lot of people and therefore a lot of great ideas by not being able to think
outside of how we're all stereotyping each other.
So it's it's hard to kind of convey that and you can just say, oh, yeah, I want to be more diverse. I want to be more open, but
it's a nearly impossible problem to solve and the movie really helps open people's eyes to it.
This book I put third because
unlike the giver, people may not want to read it. It's not as relevant. But when I was in my early 20s, I went to this big, this like 800 people large conference
called run by the Wilderness Canoe Association in my hometown of Toronto. And there was a
family friend there who I met and he said, read this book, it'll change your life. And it
actually changed my life.
And it was a book called Sleeping Island
by an author, PG Downs, who just coincidentally lived
in this area, lived in the Boston area.
And he was a teacher, I think at a private school.
And every summer, he would go to Canada
with a canoe, often by himself.
And he wrote this book, maybe in the 40s or 50s,
about a trip he took in the late 1930s.
And it was, I was just shocked that even at that time, although that was a long time ago,
there were large parts of Canada that were untouched by white people.
And he went up there and interacted like with the natives.
He called the book and had a subtitle that was called, there's something like Journey
in the Baron Lands.
And when you go up North and Canada,
you pass the tree line, just like on a mountain,
if you hike up a mountain, you get so far north
or aren't any trees.
And he wrote eloquently about the land
and about being out there.
There weren't even any maps of the region,
like in that time.
And I just thought to myself, wow,
like that you could just take the summer off
and explore by canoe and go and see what's out there.
And it led to me just doing that, that very thing.
Of course, it's different now, but going out to where the road ends and putting the canoe
in the water and just, well, we had to have a plan.
We didn't just explore, but go down this rivers with rapids and travel over lakes and
portages and just really live.
So just really explore, scurry.
That doesn't like it.
It doesn't. We're just used from a topo map, from a topo graphical map, from the library.
And those things. They were scary elements about it, out of it. But part of the excitement
or the joy or the desire was to be scared. Like, I was to go out there and have live on
the edge. And persevere. Yeah. And persevere, yeah.
Do you have a advice that you would give to a young person today that would like to
help you maybe on the planetary science side, discover exoplanets, or maybe bigger picture,
just succeed in life?
I do have some advice just to succeed.
It's tough advice in a way, but it is to find something that you love doing that you're also very good at.
In some ways the stars have to align because you've got to find that thing you're good at or the
range of things. It actually has to overlap with something that actually you love doing every day,
so it's not a tedious job. That's the best way to succeed. What were the signals that in your own life were there to make you realize you're good at something?
You're like, what were you good at that made you pursue a PhD and it made you pursue the search?
I mean, that was the one sentence version. In my case, it was a long slog and there were a lot of things I wasn't good at initially.
But so initially, you know, I was good at high school math, I was good at high school science.
I loved astronomy.
And I realized those could all fit together.
Like the day I realized you could be an astronomer for a job, it has to be one of my top days
of my life.
I didn't know that you could be that for a job.
Yeah.
And I was good at all those things.
And although my dad wanted me to do something more practical, where he could be guaranteed,
I could support myself was another option. But initially, it wasn't that good at physics.
It was a slog to just get through school and grad schools a very, very long time.
But ultimately, when faced with a choice and I had the luxury of choosing,
knowing that I was good at something and also loved it. It really carried me through.
Now I asked some of the smartest people in the world, the most ridiculous question. We already
talked about it a little bit, but let me ask again, why are we here? I think you've raised
this question when your presentation says like one of the things that we kind of
assume is long to answer in the search for exoplanets is kind of part of that.
But what do you think is the meaning of it all of life?
I wish I had a good answer for you.
I think you're the first person ever who refused to answer the question.
It's not so much refusing. I just, yeah, I mean, I wish I had a better answer. I think you're the first person ever who refused to answer the question or say.
It's not so much refusing.
I just, yeah, I mean, I wish I had a better answer.
It's why we're here.
It's almost like the meaning is wishing there was a meaning, wishing we knew.
I love that.
That's a great way to say it.
So, like I said, the book is excellent.
I admire you work from afar for a while.
And I think you're one of the great stars at MIT.
It makes me proud to be a part of the community.
So thank you so much for your work.
Thank you for spying all of us.
Thanks for talking to me.
Thank you so much, Lynx.
Thanks for listening to this conversation with Sarah Seeger.
And thank you to our sponsors, public goods, power dot, Thank you so much, Lynx. on Patreon, a connect with me on Twitter, a Lex Friedman, spelled I'm not sure how, just
keep typing stuff in until you get to the guy with the tie in the thumbnail.
And now let me leave you with some words from Carl Sagan.
Somewhere something incredible is waiting to be known.
Thank you for listening and hope to see you next time. you