Lex Fridman Podcast - #378 – Anna Frebel: Origin and Evolution of the Universe, Galaxies, and Stars
Episode Date: May 19, 2023Anna Frebel is an astronomer and astrophysicist at MIT. Please support this podcast by checking out our sponsors: - Hexclad Cookware: https://hexclad.com/lex and use code LEX to get 10% off - Numerai:... https://numer.ai/lex - House of Macadamias: https://houseofmacadamias.com/lex and use code LEX to get 20% off your first order EPISODE LINKS: Anna's Twitter: https://twitter.com/annafrebel Anna's Instagram: https://instagram.com/annafrebel Anna's Book - Searching for the Oldest Stars: https://amzn.to/3pi2Ci6 PODCAST INFO: Podcast website: https://lexfridman.com/podcast Apple Podcasts: https://apple.co/2lwqZIr Spotify: https://spoti.fi/2nEwCF8 RSS: https://lexfridman.com/feed/podcast/ YouTube Full Episodes: https://youtube.com/lexfridman YouTube Clips: https://youtube.com/lexclips SUPPORT & CONNECT: - Check out the sponsors above, it's the best way to support this podcast - Support on Patreon: https://www.patreon.com/lexfridman - Twitter: https://twitter.com/lexfridman - Instagram: https://www.instagram.com/lexfridman - LinkedIn: https://www.linkedin.com/in/lexfridman - Facebook: https://www.facebook.com/lexfridman - Medium: https://medium.com/@lexfridman OUTLINE: Here's the timestamps for the episode. On some podcast players you should be able to click the timestamp to jump to that time. (00:00) - Introduction (05:26) - First elements (12:35) - Milky Way (16:11) - Alien worlds (19:16) - Protogalaxies (24:29) - Black holes (29:27) - Stellar archeology (38:42) - Oldest stars (46:32) - Metal-poor stars (1:02:05) - Neutron capture (1:07:01) - Neutron stars (1:12:30) - Dwarf galaxies (1:17:10) - Star observation (1:45:27) - James Webb Space Telescope (1:51:17) - Future of space observation (1:54:26) - Age of the universe (2:07:34) - Most beautiful idea in astronomy (2:11:23) - Advice for young people (2:20:17) - Meaning of life
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The following is a conversation with Anna Frabel, an astrophysicist at MIT studying the oldest
stars in the Milky Way galaxy in order to understand the chemical and physical conditions of the
early universe. And how from that, our galaxy formed and evolved to what it is today, the place we
humans call home. And now a quick few second mention of each sponsor. Check them out in the description.
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And now, dear friends, here's Anna for Bell. Let's go back to the early days.
What did the formation of the Milky Way galaxy look like?
Or maybe we want to start even before that?
What did the formation of the universe look like?
Well, we scientists believe there was the big bang, some big beginning.
But what is important for my work, and I think that's what we're going to
talk about is what kind of elements were present at that time. So the Big Bang left a universe behind
that was made of just hydrogen and helium and tiny little sprinkles of lithium. And that was pretty much
it. As it turns out, it's actually quite hard to make stars
or any structure from that.
That's fairly hot gas.
And so the very first stars that formed prior to any galaxies
were very massive stars, big stars,
hundred times the mass of the sun.
And they were made from just hydrogen and helium.
So, Bix does explode pretty fast.
After a few million years only, that's very short on cosmic time scales.
And in their explosions, they provided the first heavier elements to the universe,
because in their cores, all stars fuse lighter elements like hydrogen and helium into heavier ones.
And then that goes all the way
up to iron. And then all that material gets ejected in these massive supernova explosions. And that
marked a really, really important transition in the universe because after that first explosion,
it was no longer chemically pristine. And that set the stage for everything
else to happen, including us here talking today. So what do you mean by pristine? So there's a whole
complex soup of elements now as opposed to just hydrogen helium and a little bit of lithium.
Yeah, so after the Big Bang, just hydrogen and helium, we don't really need to talk too much
about lithium because the amount was so small.
And after these fair first stars formed and exploded, they have your elements like carbon, oxygen,
magnesium, iron, all of that stuff was suddenly present in the gas clouds.
all of that stuff was suddenly present in the gas clouds.
Tiny amounts only, very tiny amounts, but that actually helped, especially the carbon
and the oxygen to make the gas cool.
These atoms are more complicated than hydrogen,
that's just a proton.
And so it has cooling properties,
can send out photons outside of the gas cloud.
So the gas can cool.
And when you have gas that gets colder and colder, you can make small and small
a star so you can fragment it and clump it and turn it into stars like the sun.
And the cool thing about that is that when you have small stars like the sun,
they have a really long lifetime.
So those first low mass stars that formed back then are still observable
today. That is actually what I do. I try to find these early survivors because
they tell us what the gas looked like back then. They have preserved that
composition of these early gas cloud, the chemical compositions, until today.
So I don't need to look very far into the universe, to study all the beginnings.
I can just chemically analyze the oldest stars, and it's like unpacking everything that
happened back then. It's very exciting.
So to just reiterate, so in the very early days in the first few million years There was giant stars
That's mostly hydrogen helium and then they exploded in these supernova explosions and then they made these clumps
Yeah, so the first team
Not pristine clumps. Yeah pretty much fun. So it took a few hundred million years for the first stars to emerge
Yes, and then they exploded after a few million years
for the first stores to emerge. And then they exploded after a few million years,
Kaboom.
And then it's like, I always consider the universe
like a, you know, a nice soup.
And then these first soup and over explosions
kind of provided the salt, you know,
just a little sprinkle of heavier elements
and that made it really tasty.
It's just changed it completely, right?
And that changed the physics of the gas. So that
meant that these gas clouds that were, you know, surrounding the the former first stars, they could
now cool down and clump and form the next generation of stars that now included also little stars.
And as I just mentioned, the small stars have these really long lifetimes.
The Sun has a lifetime of 10 billion years. Any star that is even less massive will have
an even longer lifetime. So that gives us a chance to still observe some of the stars
that form back then. So we are testing the conditions, the chemical and physical conditions
of the early universe even before the galaxy formed.
So what's the timeline that we're talking about?
What is the age of the universe and what is the earliest time we got those salty, delicious
soup, clump soups with heavier elements?
Well, the universe is 13.8 billion years old.
Allegedly, yeah.
Is it?
13 brain, sorry.
Well, when I was in high school, the universe was 20 billion years old.
Yeah. So the estimate, do you think that estimate will evolve in interesting ways or no? Is
that as it's pretty stable? Mostly converged. Yes. Because the techniques are very different now,
much more precise. The whole business of precision cosmology by mapping out the cosmic microwave background,
that's a marvelous feat. Maybe the digits will still move around a little bit, but that's all right.
Well, the gravitational waves and all that, it's all the different sources of data.
Mapping out this detailed picture of the early universe.
Totally. We think the earliest little stars formed,
I don't know, maybe half a billion years after the Big Bang, right? Again, a few hundred million
years for the first stars to emerge and then, you know, took some time. So give or take half a
billion years. And that was the time when sort of the very first proto-galaxies formed early stellar structures, stellar systems
from which the amicuate eventually formed, right? So the amic was probably a slightly bigger
one and we know today that galaxies grow hierarchically, which means they eat their smaller
neighbors. So if you're the bigger one and have a few, a few friends around, you're just going to eat them, absorb them, and then you grow bigger.
And so all these, these little early stars, you know, kind of came into the
make-away through that kind of process. And that's why we find them in the
outer parts of the galaxy today, because they're just kind of deaf and just left there since. So the old stuff is on the outsk parts of the galaxy today because they're just kind of deaf and just left
there since.
So the old stuff is on the outskirts of the galaxy and the new stuff is in close to the
middle.
Broadly speaking.
Yes.
That's where you would look for it.
So maybe just a step back, like what is the galaxy?
What is a powder galaxy?
I love that question.
So the galaxy is a huge assembly of stars.
The Mickey Way contains something like 200 to 400 billion stars.
And most of the material and the stars are in the disk.
And when we look at the night sky, what we see as the Mickey Way band on the sky, that is actually the inner spiral arm because we
actually live in a spiral disc.
Galaxy is on the Milky Way spiral disc.
Galaxy, and we're looking, actually depends a little bit in the northern hemisphere.
We're looking out of the galaxy.
So we're seeing the next outer spiral arm. And as you can imagine, there's only dark space behind that. So we don't see
it all that nice on the sky. But if you travel to South to the southern hemisphere,
let's say South America, you see the macuanet looks so different on the sky
because that's the next inner spiral arm. And that's backlit by the Galactic Center.
The Galactic Center is a very big puffy region of gas.
There's a lot of star formation.
The Galactic Party is happening there.
So it's very bright and it makes for this very beautiful make you way on the night sky
that we see.
So actually, if you ever get the chance to experience that, I encourage you to almost
like close your eyes while seeing this and imagining that you're sitting in this kind of
disc, in this pancake, and you're just kind of looking right into it.
And you can really feel that we're in this 2D disc.
And then you can imagine that there's a top and a bottom,
and that we're really part of the galaxy. You can really experience that.
Not just lost in space somewhere, but we're really a part of it. And,
you know, knowing a little bit about the structure of the Mikiwa really helps.
Do you feel small when you think about that? When you look on that spiral on the inside of the Milky Way and then you look out to the outside
How are we supposed to feel?
I don't know. I don't feel small necessarily. I feel in awe and I feel I'm a part of it because I can really feel that I'm a part of it.
I think for many people they think like oh, there's just the planet and then there's nothing.
And that's almost a little bit sad, but that's really not the case, right?
Because there's so much more and I really like to imagine how I'm sitting in this big
galactic merry-go-round and we're going around the center and I can see the center above me, right?
And I can almost feel like we're going, going
there. Of course, we can't really feel that. But the sun does circle the galactic center.
But there's a kind of sadness to like looking pictures of a nice vacation place. All we get is
that light, an old light. Do you feel like sad that we don't get to travel or you and I will
not get to travel there and maybe humans will never get to travel there?
Yeah, I always wanted to travel into space and see the earth and other things from up there.
They are certainly that, but I don't know. It's also okay to just be at our vantage point and see it from here.
With the sensors, with the telescopes that we have and explore the possibility.
I mean, there is a kind of wonder to the mystery of it all. What's out there?
What interesting things that we can't possibly imagine. There could be all kinds of life forms, bacteria, all this kind of stuff.
I tend to believe that,
it depends on the day. I tend to believe there's just a lot of very primitive organisms
just spread out throughout.
And they build there with little things
like bacteria, tip organisms.
And just to think what kind of worlds there are
because they're probably really creative living organisms.
Because the conditions, I guess the question I'm wondering
to myself when I look out there to the stars, how different are the conditions on the
different planets that orbit those stars?
Well, definitely be very different. I mean, the variety out there is huge. We know now
that I think it's about every other star has at least one planet.
I already mentioned the number of stars in the galaxy.
I mean, it's a huge number of planets out there.
So who knows what that looks like.
All we know is that there is.
There is a lot of variety.
We don't quite yet understand what drives that, what governs that, why that is the case,
why is it not all one size fits all?
We mean the dynamics of planet formation,
like exoplanet formation or star formation,
the whole thing.
All of it, all of it.
Star formation is, remains a much research topic.
We kind of, we definitely know that it works.
Because all the stars are there, same for the planets.
But the details are so varied per gas cloud, right?
It's very hard to come up with very detailed prescriptions.
Broadly, we have figured it out.
You need a gas cloud, you need to cool it, something clumps and fragments,
and somehow it makes the start with planets or without.
But the dynamics of the clumping process is not fully understood?
No, no. And the local conditions are so varied, right? I mean, it's the same with, you know,
all people look like people, but individually we look very different.
So even the subtle diversity of the formation process creates all kinds of fun differences?
Yes, so we just don't know how this turned out in an individual case.
And it's kind of hard to figure it all out and to take a look certainly with planets,
right?
The chance for ever to ever actually take a picture of a planet is miniscule because they
don't shine.
It's not that really dark.
So I'd say there's a lot of possibility out there,
but we have to be a little bit more patient.
For people who are being...
Yeah, come up with technologies
where patients become less necessary
by extending our lifetimes
or increasing the speed of space travel, all the kind of stuff.
He was a pretty intelligent, they're pretty, uh, the most part.
I hope, I'm not, what I'm on the optimistic days.
Well, maybe just the linger on the, on the, what a galaxy is.
What should we know about our understanding of black holes in the formation? Is that an
important thing to understand in the formation of a galaxy? So all the orbiting, all the
sparring that's going on, how important is that to understand? All of the above. That's what makes
astronomy really hard, but also really interesting, right? No day is like another because we always
find something new. I want to come back to
the idea of the proto-galaxy because it actually matches or you know relates to the black hole formation.
So most large, well pretty much all large galaxies have a supermassive black hole in the center.
And we don't actually know, we don't really know where they come from. Again, we know that they are there, but how do we get there?
So, we go back to the early universe, right? We had a little galaxy that just sort of,
you know, I don't know, had some small number of stars. It was a first,
gravitationally bound structure that was held together by dark matter, because dark matter
actually kind of structured up first before the luminous matter could, because that's what
dark matter kind of does.
And it started to hold gas and then start sort of together in this first very shallow,
what we call potential well, so these curvitationally bound systems, and then
the make-you-a-grue from absorbing,
neighboring, smaller, even smaller systems.
And somewhere in that process,
there must have been a seed for one of
these supermassive black holes, and I'm
not actually sure that it's clear right now
kind of what was their first, the super supermassive black hole or the galaxy.
So lots of people are trying to study that.
And of course the black hole wasn't as massive back then
as it is these days.
But it's a big area of research
and the new James Webb, the JWT, the telescope,
the infrared telescope in space is working on,
many people are working on that to figure out exactly what happened, and there are some
surprising results that we really don't understand right now.
So to solve the chicken or the egg problem of, do you need a supermassive black hole to form a galaxy
or does the galaxy naturally create the supermassive black hole?
Yeah, yeah.
I mean, I think to some degree, we can answer that
because there are lots of little dwarf galaxies out there.
The Milky Way remains surrounded by many dozens
of small dwarf galaxies.
I have studied a bunch of them.
And to the extent that we can tell, they do not contain black holes.
So they are certainly were gravitationally bound structures.
So either you can call them proto-galaxies or dwarf galaxies or first galaxies, they were
definitely there.
But there must have been bigger things like the proto-miccule where something was different,
right? What made them more
massive so that, you know, they would curvitationally attract these smaller systems to integrate them.
So we'll have to see. How do we look into that, the dynamics of the formation, the evolution of
the proto-galaxies? Is it possible? Did they shine? I mean, what are the set of data that we can possibly look at?
So we've got gravitational waves,
which is really insane that we can even detect.
Yeah.
There's light.
What else can we, uh...
So that would fall into the category
of observational cosmology.
And the JWST is the prime telescope right now to
and it promises big, big steps forward. This is in its early days because it's only been online
like a year or so. But that collects the infrared light from the furthest, like literally proto-galaxies,
earliest galaxies, that light has traveled
some 13 billion years to us,
and they're observing these faint little blobs.
And folks are trying to, you know,
again, study the onset of these early,
supermassive black holes, how they shape galaxies.
So they are seeing that they are there, you know,
surrounded by already bigger galaxies.
Ideally, I'd like for my colleagues
to push a little bit further.
Hopefully, that will eventually happen.
In terms of looking towards older and older.
Yeah, yeah, more and more sort of primitive
in terms of the structure.
But of course, as you can imagine,
if you make your system smaller and smaller, it becomes dimmer and dimmer, and it's further and further away. So we're
reaching the end of the line from a technical perspective pretty quickly.
But it's dimmer and dimmer means older and older.
Yes, in a sense, because it all started really small.
Yeah. Because it's smaller, smaller, which correlates to older. In that phase of the universe, it would otherwise, it doesn't.
Just to take a small attention about black holes. And you know, because you do quite a bit of
observational cosmology and maybe experimental astrophysics, what's the difference to you between theoretical physics and
experimental? So there's a lot of really interesting explorations about paradoxes
around black holes and all this kind of stuff about black holes destroying
information. Do those worlds into mixed you when you especially when you step away
from your work and kind of think about the mystery of it all. Well, at first glance, there isn't actually much crosstalk. Personally, I mostly observe stars,
so I don't usually actually think too much of black holes. And stars as a fundamental kind of
chemical, physical phenomena that doesn't. That's right, the physics is kind of different. It's not extreme.
I mean, you could consider a nuclear fusion sort of be
perhaps extreme.
You need to tunnel.
That is some interesting physics there.
But it's just a different flavor.
I don't do these kinds of calculations myself either.
I very much like to talk with my theory colleagues about these things though,
because I find there's always an interesting intersection. And often it's just, I've written a
number of papers with colleagues who do simulations about galaxies. And so they're not quite as far removed
as, let's say, the black hole, you know,
pen and paper folks.
But even in those cases, we had the same interest in the same topics, but it was almost like
we're speaking two different languages.
And we weren't even that far removed, you know, both astronomers and all.
And it was really interesting just to take that time and really try to talk to each other.
And it's amazing how hard that is.
Even amongst scientists, we already have trouble talking to each other.
Imagine how hard it is to talk to non-scientists and other people
to try to...
We're all interested in the same things as humans at the end of the day, right?
But everyone has sort of a different angle about it and different questions and way of
formulating things and sometimes it really takes a while to converge and to get to the
common ground.
But if you take the time, it's so interesting to participate in that process and it feels
so good in the end to say,
yes, we tackled this together.
We overcame our differences, not so much in opinion,
but just in expressing ourselves about this
and how we go about solving a problem.
And these were some of my most successful papers
and I certainly enjoyed them the most.
It can also lead to big discoveries.
I mean, I think you put it really well in saying that we're all kind of studying
the same kind of mysteries and problems.
And I see this in the space of artificial intelligence.
You have a community, maybe it seems very far away, artificial intelligence and neuroscience.
You know, you would think that they're studying very different things.
But one is trying to engineer intelligence and in so doing try to understand
intelligence. And the other is trying to understand intelligence and cognition in the human mind.
And they're just doing it from a different set of data, different set of backgrounds
and the researchers that do that kind of work. And probably the same is true in observational cosmology and simulation.
So it's like a fundamentally different approach
to understand the universe.
Let me use for simulation, let me use the things I know
to create a bunch of parameters
and create some, just play with it.
Play with the universe, play God,
create a bunch of universes and see in a way that matches
experimental data.
It's a fun, it's like playing Sims, but at the Cosmic level.
Yes, yes.
But then probably this side of terminology used there is very different.
And maybe you're allowed to break the rules a little bit more.
Let's have, you know, yeah, it's like the Drake equation.
Yeah, you don't really know, you kind of come up with a bunch of values here and there and just see how it evolves
and from that kind of into it, the different possibilities and dynamics of the evolution
of a galaxy, for example. Yeah, but it's cool to play between those two because it seems
like, we understand so little lot of our cosmos. So it's good to play.
Yes, it's like a big sandbox, right? And everyone kind of has a little corner and they do things,
but we're all in the same sandbox together at the end of the day.
But in that sandbox does have super powerful and super expensive telescopes.
That everybody's also, all the children are fighting for the resources to make sure they get to ask the right questions using that big cool tool.
Can we actually step back on the big field of stellar archaeology?
What is this process? Can you just speak to it again? You've been speaking to it.
What is this process of archaeology in the cosmos? cosmos. Yeah, it's really fascinating. So I mentioned the lesser the mass of the star,
the longer it lives. And again, for reference, for the next dinner party, the Sun's lifetime is
10 billion years. So if you have a star that's 0.6 or 0.8 solar masses, then its lifetime is going to be
solar masses, then its lifetime is going to be 15 to 20 billion years. And that's an important range for our conversation because again if you assume that such a
small star formed soon after the Big Bang, then it is still observable today.
You mentioned old light before. Yeah, that light is like a few thousand years old, but compared to the age of these stars, it's nothing.
So to me, that's young.
It comes straight from from a galaxy.
Oh, you know, it's not far.
These stars are not far away.
They're in our galaxy in the outskirts.
They probably did not form in the galaxy,
because again, hierarchical assembly of a Milky Way event. Exactly.
They formed in a little other galaxy in the vicinity, and at some point the Milky Way
ate that, which means absorbed all the stars, including these little old stars that are
now in the outskirts of the Milky Way that I used to point my telescope to.
So what can we learn from these stars? Why should we study them?
Now these little stars are really, really efficient with their energy consumption. They are still
burning for the experts, just burning hydrogen to helium in their cores and they have done so for
the past 12, 13 billion years, however, all they are. And they're going to keep doing that for
another few billion years. Same as the sun, the sun also just does hydrogen, helium, however, all they are. And they're going to keep doing that for another few
billion years. Same as the sun. The sun also just does hydrogen-dillion burning and will continue
that for a while. Which means the outer parts of the star, well, pretty much actually most of the
star, that gas doesn't talk to the core. So whatever composition that that star has,
you know, in its outer layers,
is exactly the same as the gas composition
from which the star formed,
which means it has perfectly preserved
that information from way back then
all the way to the day and going forward.
So I'm a stellar archaeologist because I don't dig in the dirt to find remnants of past
civilizations and whatnot.
I dig for the staff of the old stars in the sky because they have preserved that information
from this first billion year years in their outer stellar atmosphere,
which is what I'm observing with telescopes.
So I'm getting the best look
at the chemical composition early on
that you could possibly wish for.
What kind of age are we talking about here?
We're talking about something that's close to that,
like a 13 billion, 12, 13 billion
age range. That's what we what we think. Now, there's a small caveat here. We cannot accurately
date these stars, but we use a trick to say, oh, these stars must have formed as some of the
earliest generations of stars, because we need to talk about the chemical evolution of the universe in the Milky Way for a second. So I already mentioned the
the pristineness of the universe after the Big Bang, right? Just hydrogen and helium.
Then the first stars formed, they produced a sprinkle of heavier elements up to iron.
Then the next generation of stars formed, that included
again massive stars that they would explode again, but also the little ones that keep on living,
right? So, and then the massive ones again explode as supernova, so they provide again another
sprinkle of heavier elements. And so over time, all the elements in the periodic table have been built up.
There have been other processes, for example, neutron-star mergers and other exotic supernovae
that have provided elements heavier than iron all the way up to uranium from fear early
on.
We're still trying to figure out those details, but I always say pretty much all the elements were done from day three.
So iron is where, once you get to iron, you got all the fun you need.
Most of the fun.
Yes, I know.
I really like the heavier elements, you know, golds of platinum, that kind of stuff.
For personal reasons or for star formation.
What's the importance of these heavier metals in the evolution of the stars?
So they're the spice of life.
So every supernova gives you elements up to iron.
That's cool, but at some point it gets a little bit boring because that always works.
But that's the baseline. We need that. And that's certainly what came out of the first stars,
and then all the other supernova explosions that followed with every generation. And it took
about a thousand generations, give or take, until the sun was made. So the sun formed from a gas cloud that was enriched by roughly
thousand generations of supernova explosions, and that's where the sun has its chemical
composition that it has, including, you know, and somehow the planets were made from that
as well. So the supernova explosions, the many generations
are creating more and more complex elements. No, it just goes all the way up to iron. Yeah, and then it's just a little bit more of all of these elements. Just more. Yeah, just
Yeah, it's one sprinkle than another and it just kind of adds up, right?
Now the heavy elements form in very different ways. They are not fusion made. They are made typically through neutron capture processes, but for that you
need seed nuclei, ideally, you know, iron or carbon or something. So they're supernova made
elements are a very good seed nuclei for other processes that then create heavy elements.
And because they cannot be made everywhere, they when you when you know, so I my some of
my stars have huge amounts of these heavy elements in them and they tell us in
much more detail
something really interesting happened
somewhere. Well wait, I thought I thought the really old ones we would not have so what does that mean if the old one?
Yes, important clarification. So
the stars that we are observing today these these old ones, they form from the gas and the question is, what enriched that gas?
So, it could have been just a first star dumping their elements into that gas all the way up to iron. And we have found some stars that we think are second generation stars.
So they form from gas and reached by just one first star.
That's super cool.
Then we find other old stars that have a much more complicated
heavy element signature.
And that means, okay, they're probably formed in a gas
cloud that had a few things going on, such as maybe a first star, maybe another
more normal supernova, and maybe some kind of special process, like a neutron
star merger, that would make heavy elements. And so they created a local chemical signature from which the next generation
star then formed. And that is what we're observing today. So all these old stars basically
carry the signature from all their these progenitor events. And it's our job then to unravel
okay, which processes and which events and how many,
you know, may have occurred in the early universe that led to exactly that signature that we
observed 13 billion years later?
Is it possible to figure out like the number of generations that resulted in these stars?
Well, we can, we think we can sort of say, okay, this was like second generation or third,
because the amounts of heavy elements in the cells that we observe is so tiny.
One normal supernova explosion is actually already basically too much.
It would give us too much of it. And the thing is, you can never take away things in the universe. You can only add.
There's no cosmic vacuum cleaner going around sucking things away. Black holes are probably the
closest to that, but they would have taken the whole stuff out of the gas. So we have a maybe
So we have maybe 10 stars or so now where we are saying that they contain so little of these heavy elements that there must be second generation because how else would you have made them?
And again, I want to stress that the elements that we observe in these stars were not made by the
stars themselves that we observe. That's just a reflection of the gas class.
So we don't actually, I had to say that because I love stars.
At the end of the day, we don't really care for the stars that we're observing.
We care for the story that they're telling us about the early universe.
So the stars are kind of a small mirror into the early universe.
Yeah.
So what are you detecting about those stars?
Can you tell me about the process of archaeology here?
Like what kind of data can we possibly
get to tell the story about these heavy elements on the stars?
Yeah, it depends really on what star you find.
There are many different chemical signatures.
We actually pair up these days our element signatures
with also kinematic information, how the star moves about the galaxy that actually gives
us clues as to where the star might have come from because again all these old stars are
in the galaxy but they are not off the galaxy.
That's a small but important distinction.
So they all came from somewhere else.
So you can rewind back in time,
kind of estimate where it came from?
Yeah, so we kind of really say,
oh, it came from that and that drawer of galaxy,
but interestingly, now so I'm just a few days ago.
I submitted a paper with three women undergrads.
It was so good to work together and we found a sample
of stars that have very, very low abundances in strontium and barium, so very heavy elements.
And I had a hunch for a while that these stars would probably be some of the oldest
because, as I said, heavy elements give you extra information about special events.
And again, finding something that's really low means that must have happened either really early
on or in a very special environment, right? Because we can only ever add.
So if you find something that's incredibly low in terms of the abundance,
maybe just one event contributed that max.
So we looked at the kinematics,
how are these stars moving?
And they're all going the wrong way in the galaxy.
Hello.
How is that possible?
Well, it is possible because now we come back to the proto to the proto galaxy the proto galaxy was like a beehive
It just didn't really know what it was or what I wanted to become when it grew up
So and it was absorbing all these little galaxies to grow fast
some
Galaxy some absorbed galaxies
We're thrown in going the main way and some came in the wrong way, huh?
Happens. Yeah happens, but this could only happen early on when you know, there wasn't left and right and up and down
So stuff would come in from always so now
13 billion years later. We're still doing it. Yeah, they're still doing it and be yeah
We just looked for stars that have low stratium and barium abundances.
And then we look at the kinematics
and lo and behold, they're all at hundreds of kilometers
per second going the wrong way.
It's like, dude, you must have come
and really early on from somewhere else.
So we call this retrograde motion.
That's a clear sign of accretion.
So something that has come into the galaxy
and because they are so fast,
and it's really all of them,
that must have happened early on, right?
You can't throw a galaxy into the Mickey Raid
right now the wrong way,
it eventually will turn around.
Can you actually just,
a small tangent speak to the three women undergrads like this little
it's pretty cool that you were able to use a hunch to find this really cool little star.
Yeah, what's the process of like especially with Lonegrads I think they'll be very interesting
and inspiring to people. Yeah, so it was a wonderful little collaboration that actually emerged in the fall. I, so I like, I really like working with, with undergrad and grad students, postdocs.
And I came up with a new concept for a class at MIT, where I wanted to integrate the research
process into the classroom.
Because sometimes people find it really hard
to call email a professor, hey, I'm this and that person,
and I'm interested in your research
could possibly come.
And I wanted to streamline that and give,
and it not just trial, how it would work
to provide a sort of the safe confines
of a classroom where you just sign up
and do research in a very structured way.
And I developed it, was a lot of work,
a little bit more than I thought,
to map up an entire research project basically
from scratch in 10 work sheets,
so that they could do it again in a very structured
and organized fashion. So you created this whole framework for it to do it? Yeah, the whole thing.
But the promise was, you come sign up for my class in Teams of Two, you each get your own old star
that has not been analyzed before. I don't know what the solution is because in research,
we don't look up the solution at the end of the book.
We do not know what we're going to find.
Our job is to do the work and then to interpret the numbers
because our job as scientists is to find the story.
Anyone can crunch numbers.
Anyone. It's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it's it And you need to kind of see the universe in 3D. You just need to kind of go for it. And that's the beautiful thing.
I really love that.
And so this was a story of weird kinematics
going the wrong way combined with this particular weird
signature in terms of the elements.
Exactly.
And you have to come up with a story of that.
Yes.
And so the story of that paper is now, usually I don't say
I find the oldest stars, when I talk to my research colleagues,
I talk to them about we find the chemically most pristine stars
because that's actually what we measure,
the chemical abundance that tells us,
okay, it must have been second or third or fifth generation
of stars, right?
But these low strontium stars that go in the wrong way,
like they're getting paid for it,
they must be the oldest stars that came
into the galaxy because they formed before the galaxy was the make-away, right? And it's
so cool and it was so wonderful. So this class, it went so well in the fall, I had nine people
sign up, that's not unusual for a class at specialty class at MIT, so small
number. It was eight women and they were so into it that I said, okay, let's use
this opportunity, you're gonna do some extra work with me and we're gonna
publish this. I also like that you're using the terminology of chemically
more pristine. When I'm talking to younger people
I'll just say that I'm more chemically pristine than them. I like that description of age
So there's this term of metal poor stars
So most of these old stars are going to be metal poor. Yes
I searched for the most metal poor stars. And what is that? Can we just define? Yeah, what does that mean?
I don't know who came up with this. I would I would love to know, but
the universe is a complicated place. So many decades ago, someone clever came up with the idea to say,
let's simplify things a little bit. Let's call hydrogen X helium Y and all the other elements combined metals. Z. Okay.
When I give public talks, I was asked, I said, I said, I'm a chemist in the audience.
Let me just tell you, neon is a wonderful metal. Oh my god. What's he saying? I'm in
astronomy. I'm not a chemist, so I'll get away with it. So if you just roll with it for a moment, all the elements except hydrogen and helium
are called metals.
Now if we look again at the concept of chemical evolution, it means more and more off all
the elements, everything higher than hydrogen and helium gets produced slowly by surely
by different types of stores and events.
So that's a monotonyously increasing function.
And so we look for the stars that have the least amounts of heavy elements in them, because
that means we are going further and further back in this process in that function, almost
all the way to the very beginning,
and that is the first start, right?
They started that process.
That's why I said it was such an important transition phase,
because it thinks we call,
you know, the post-big bang universe pristine,
just hydrogen helium,
and after that the mess started.
If you soon as you add elements to it,
things kind of get a
little out of hand. That ends in this beautiful variety that we have everywhere these days.
And you're looking at the very early days in the introduction of the variety.
Yes, exactly. When it was still a little bit more organisable.
But the variety of different types of metal per stars, we have a stark,
many different types of stars, many patterns we have sort of identified,
but they are still crazy ones out there that we're still trying to kind of fit in.
So what kind of stars have been discovered?
So you've already a while ago,
helped discover the star H.E. 1327, 2326.
Great name.
Yes.
And H.E. 1523, 0901.
What can you say about these stars and others that have been found?
I love them.
They're my baby stars.
What do you call what do you call what do you call your your baby stars?
Well, I'm probably the only one who can you know spit out these names without cheating. There's nicknames.
Are there nicknames? No, that's that's that's that's not allowed. Okay. Well some colleagues at conferences have just called them Anna
star freeble star because they they didn't want to learn the the phone number, you know, I get a number.
they didn't want to learn the phone number, you know, I get it. Phone number.
And these numbers are actually based on older sets of coordinates for these stars.
So they, yes, the minus in the middle means that they are in the Southern Hemisphere,
so the Southern Hemisphere, positive is in the Northern.
And then 13 and 15 means that's sort of observable in the middle of the year.
Okay, so that's the deal with the observation and where it was observed in the next couple of years.
Yes, yes, yes.
But they have very different stars, both absolutely significant, career defining, actually
for me, but really pushed the envelope in very different ways.
So at E1327, the first one that you mentioned, that was the second generation star that
we found.
And usually people say, like, oh, the first one is a big one and the rest is nobody cares.
But to us, it proved that, yes, we can do it.
Because one, astronomers live in a sort of way of, you know, there are a lot of serendipitous
discoveries and we, that's really great,
but we need to show that we can do it again. Because then we're on to something and it's not just
some kind of weird quirk and there are a lot of quirks in the universe, but we want to know,
is that a real thing? Does that happen regularly? Is there something that we can learn? Is that a piece
of the story? And so finding the second one that was even a little bit more extreme than the first
one really showed, yes, our search techniques work, we can find these stars.
They provide an important part to the story in a sense that if we had more than two stars, and by now we have about 10ish or so, what do they tell us
about the nature of the very first stars? And what we found again working with the theorists,
of course, who run the supernova models is that, so actually let me, let me, before I get into this,
is that, so actually, let me, let me, before I get into this, these two stars had huge amounts of carbon relative to iron. So we usually use iron as a reference element for what we call
the metalicity. So the overall metal content, the overall amount of heavy elements in it.
So that's why it's called iron deficient. That's right.
So these stars are incredibly iron deficient,
which means there must be of the second generation
because there was an interestingly enough,
there was this discrepancy, a normal supernovae,
until then we thought would get us so much iron, you know, you would distribute
that in the gas cloud and then you would form this little star that we're observing.
But the iron abundance that we measured was actually much lower than that.
And I already mentioned, you can't take things away.
That must mean these early massive pop three, we call them population three, the first
stars, they must have exploded
in a different way than we previously thought. They can't output as much iron because they
just can't. Otherwise it wouldn't match our observations. Got it. And so that's when we
started to work with several theory groups on on supernova yields. So what comes out of from the explosion of the supernova,
that's cool, supernova yields. And so this one was not yielding much iron.
Well, we needed to concoct a theoretical supernova that made less. And it's actually
surprisingly difficult because you can always add more in the universe, right? But you can't take stuff away.
So, Japanese colleagues kind of came up with the idea of a fainter supernova that just doesn't
have much, it's enough oomph, you know, when it explodes. So somehow there's less iron coming out.
But at the same time, then these stars showed huge overbanances of carbon,
you know, a thousand times more carbon. So how do you now get a thousand times more carbon
out of these poor first supernovae? That was the theoretical challenge. And because we
didn't have just one star, but two, that really spurred the field to think about what was the nature of the first stars?
How did they explode?
What are the implications?
Because if they are not as luminous and bright and energetic, that has consequences for
these early proto-galaxies in which they must have been located in terms of blowing the
gas out, let's say, and disrupting the system. So much higher chance for the earlier system to stay intact
for longer, right? So there's a whole tale of consequences. And this is what I mean with
we need to find the story because you do one thing and like the dominos, their consequences
everywhere. And then you have a different universe, right? So what could possibly be a good explanation
for something that yields a lot of carbon,
and it doesn't yield a lot of iron?
Well, it's not so much an explanation,
more like finding a mechanism for what happens in supernovae
and the official term, what was sort of,
as I said, co-cooked up in order to explain the observations.
And we have, by the way, found a whole bunch more of these tasks,
so that holds.
And it's called a fallback mechanism,
so actually during the supernova explosion
a massive black hole emerges.
And so some of the material falls back onto the black hole.
Oh, boy.
So here is a vacuum cleaner now plopped into the middle, right?
Like a temporary one that just cleans up some of the elements.
Well, sort of, right?
Because if you think of the, we haven't talked about this yet,
but if you know what a star looks like,
a master star looks like on its interior before it explodes,
you have hydrogen helium still on the outskirts,
and then you have layers of heavy and heavy elements all the way up to iron. So you have an helium still on the outskirts and then you have layers of
heavy and heavy elements all the way up to iron. So you have an iron core in the center.
And because you can't get any energy out of iron when you want to fuse to iron atoms anymore,
that's when the supernova explodes. It occurs really. It's actually an implosion first and then
you have a bounce of the sort of neutron
star phase that occurs in the process and then it gets disrupted. Yeah, it's like this
giant basketball and then it all goes out. Explosion first, explosion. Yeah. And so in the process,
if you make your black hole basically big enough, it will suck away some of the iron because that's the closest in the in terms of the layers.
You you you you you hold on to it. You don't let it escape and carbon is much further out. You let it all go.
Nice. And so that explains why you can have a big oomph and not much iron yield. Yes. Yes.
So is this explain the HG1327?
Correct.
And others like it.
Yes.
So there's a, there's, well, establish now that the lower the iron abundance of the stars
are, the higher the carbon sort of gets.
And carbon is such an interesting element in that regard. If we come back to the formation of the first
low-mestas, right, so we had the hotter gas, just hydrogen and helium, that made the first
stars. They were 100 solar masses also because the gas couldn't cool enough. So they were
big and puffy. Carbon then, coming from the first stars stars probably led to enough cooling in these gas clouds
that enabled the formation of the first low mass task.
So think about what happened if there wouldn't have been any carbon or the properties of the
carbon atom would be different.
It would not have cooled the gas in such significant ways perhaps.
There wouldn't be any low-mass
dust.
We wouldn't be here today, right?
And we're carbon-based.
And so I think carbon is really the most important element in the universe for a variety of reasons
because it is just enabled this whole evolution that we are not observing and literally seeing
in the sky.
And it's really fascinating.
So, combined with the fact that you have the iron deficient, so all of that is probably
important to creating humans.
Yeah, yeah, we need all the elements, but if you don't have stars, you know, like the
sun, small stars, that can actually host planets that have long lifetimes, you need long,
long lifetimes if you want to have a stable planet and develop humans.
Carbon is kind of important in many ways. Yes. Yes. This is perhaps a interesting tangent. If I could
just mention that you interviewed a military dresser house of carbon queen, the remarkable life
of the nanoscience pioneer. Is there something you could say about the magic of carbon and the magic of mille?
Well, mille was certainly magic. She was a professor at MIT for many decades. I met her a number of times. Her
photograph, actually a young and an older mille is still on the wall every time I step out of the elevator
in one of the buildings I see it. She pioneered all sorts of carbon
nanowork so she is a was material scientist. Very far removed from what I do in a daily basis.
But yes, carbon has amazing properties when you study it. And again, that's
indeed another aspect of why carbon is so fascinating, not just in the cosmos, but also for us,
making us, creating us in a way that we can use it. It's wonderful.
You sometimes think about this chemical evolution in this big philosophical way
that we're where the results of that chemical evolution like we're made of this stuff.
We're made of carbon. Yeah, we're made of store stuff. Yeah, and it came.
I can go right. I mean, it's almost like a cliché statement, but it's also a material, a chemical or physics statement
that came from hydrogen and helium.
And somehow this formation has created this interesting complexity of soup that made us.
What are we supposed to make of that?
Like, do we just get really lucky?
Why do we get all this cool stuff?
Yeah, that's a good question.
I don't think it's a question as an answer. I keep just asking why.
Yeah.
But it's just this incredible mystery. So much cool stuff had to happen. So much, sorry,
hot stuff had to happen.
Right. And so much could have gone wrong and there would have been another outcome, you
know. And it's actually amazing how many things kind of fell in place.
I mean, maybe that's also sort of self deterministic in some ways, right?
We are who we are because that was the path.
Maybe we would have ended up being robots. I don't know.
But it's certainly wonderful to, you know,
as scientists for us to help contribute
and rambling our cosmic history, right?
I always say the biological evolution on Earth
was, you know, absolutely facilitated
by the chemical evolution of the universe, right?
And one doesn't go without the other.
And that evolution, from a human perspective.
That evolution seems to be creating
more and more complexity.
The kind of interesting clumping of cool stuff
seems to be accelerating and increasing.
And it's hard not to see as humans
that there's some kind of purpose to it.
Like a momentum towards complexity and beauty, you know?
Well, beauties in the eye of the beholder.
But yes, everything gets more complicated.
Well, there's also beauty to the chemically pristine universe
in the early days.
Certainly, yes.
I love the desert, it's nothingness.
Yeah.
It has so much aesthetics and appeal.
We came from nothing, we'll return to nothing.
So what about HE 1523?
What's exciting?
A red giant star.
Yes.
That's another one of your babies.
Yes.
13.2 billion years old.
Yeah.
So that one isn't quite as iron deficient as the other one.
So probably not a second-generation star, but easily,
third, fourth, fifths or so, we can't really pin it down,
but it's also not super important for us.
What is important is that that star
has a very different chemical composition, in a sense,
that yes, we have all the elements up to iron there.
They have sort of normal ratios, which means kind of the same as most other old stars, and not two
different from the sun, or at least, you know, different in quantifiable ways.
But it has this huge overload of very heavy elements. And what was so nice about that
stand, particular was that I could measure the thorium and the uranium abundance. And again,
that was the second of its kind, but the uranium abundance could be more well determined. So we had a better grasp on that. Now why
are thorium and uranium interesting? They are radioactive elements. They decay. Thorium has
a half-life of 14 billion years, I believe, in uranium of 4.7, which two folks on us on Earth is a really long time, but those kind of timelines are
really good when you want to explore the early universe.
So there are two questions now that kind of come to mind, where do these elements come
from?
And what do they tell us, right? And these, as we know, these heavy elements are made in a specific
process. It's a neutron capture process, usually referred to as the R process for rapid neutron
capture process. We talked about seed nuclei before, right? So we still don't exactly know where this process can occur. So you have, let's
say, a lone iron atom somewhere and it is in an environment where you have a strong neutron
flux, which means then must be lots of neutrons around. And again, when we talk about the side,
we can supplies and ponder where that might be the case. But you have this iron atom and
you bombarded with neutrons
and you do it incredibly fast.
Now, what happens in the process?
That iron atom, you collect lots of neutrons,
it becomes really big and unstable.
So it's a heavy neutron rich nucleus that wants to decay.
Because it's not stable, it's way too big.
And so let's say you add only one neutron to decay, because it's not stable, it's way too big.
Let's say you add only one neutron to it,
that would already make it unstable.
It has a characteristic decay time,
that's called the beta decay time scale,
so it will decay to a stable nucleus.
The neutron will convert to a proton, and that makes it stable.
If you know bombard, lots and lots and lots of neutrons onto that seat nucleus within
that timescale of the beta decay, that's how you get to this huge fat neutron-rich nucleus
that then wants to decay, right?
So the rapid processes, you have your seat nuclei, they get bombarded, you create these really heavy
neutron rich nuclei, they are heavier than uranium even, the neutron flux stops and then
all these heavy nuclei, they decay and they make all these stable isotopes that we know
of all the way up to thorium and uranium.
So that rapid nuclei decay is what creates all the fun.
Correct. And the whole thing is done within two seconds. So just to add to the rapid here,
and literally the snapping on my hand, it's all there. In my talks, I often, I have this nice
simulation that illustrates, you know, this creation that illustrates this creation of these heavy nuclei.
And I always say, this is the only simulation
you will ever see that slower than real time.
Because in astronomy, we show,
oh, this is how galaxy forms,
13 billion years and 30 seconds.
Really short, right?
This is the opposite.
Me showing you this, the elements are
long, long made. So where and when does this happen? Does this process happen? So you need the strong
neutron flux. That's the clumping of the neutrons. Yes, that's right. And so there are not that many
options, right? So where do you find lots of neutrons in the universe? So it's neutron stars,
right? Neutron stars form in the making of supernovae of the explosions. Okay, so maybe some of this
heavy material gets sort of made in the making of the supernova explosion and then gets expelled.
Or you have neutron stars, so if the neutron star,
usually that's the leftover of the supernova,
if you have two from a binary pair,
so stars usually actually show up in pairs,
and so it's not too unusual to create a pair
of neutron stars that will still orbit each other
after both of their pretendeta stars have exploded. And those two neutron stars will orbit each other after both of their progenitor stars have exploded.
And those two neutron stars will orbit each other diligently.
But as we know now, thanks to LIGO,
the gravitational wave observatory, I mean,
we know already that before but now it's been measured
by LIGO is that these two neutron stars,
they will orbit each other forever.
But in the process, they will orbit each other forever, but in the process
they will lose energy.
So that orbit is what we call the orbit decays, and eventually the two neutron stars will
merge, and that results in an explosive event that has roughly the energy of a supernova,
but the process is completely different. And the cold thing is when these two
neutron stars collide, they produce a gravitational wave signature because neutron stars are super dense
objects. They are like giant atomic nucleosis. So there's a lot of interesting physics happening
already. And so if you basically form a super neutron star, by smashing
two into each other, more interesting physics happens. And that means that this is ripple
sent out into the space, the space time continuum, basically. What do people say? The ripples
of space time. It's like you drop a rock into water, right?
You see the waves coming.
So that's exactly what happens when two neutrons
does emerge.
And this is neutrons galore, right?
It's really violent to smash two neutron stars,
you know, so that are so dense already into each other.
And they, in 2017, one of these events occurred and the LIGO and Virgo
were a traditional way for observatories.
They detected that.
And then the astronomers pointed their telescopes
in that direction.
And they indeed observed what we call the electromagnetic
counterpart.
So there was something seen in the sky that
faded over the course of two weeks.
And that light curve, that light, was exactly what you get when you create all these heavy
neutron-rich nuclei in the R process, and then the neutron flag stops.
And then it takes about two or three weeks for most of them of these nuclear two-dk two-stability. So we saw, the astronomers saw in this electromagnetic
counterpart, the nuclear synthesis of heavy elements occurring. And that's
just... That's amazing. So that's the electromagnetic counterpart to the
gravitational waves that were detected
with two neutron stars colliding aggressively violently to create a super neutron star.
And that's where you get all the neutrons and neutron flux somehow.
And then that the whole shabay that happens in two seconds and creates a bunch of
factors.
So that confirmed that one of the sites for sure is for the R
process to occur is neutron
stumbergers. Interestingly enough, I
have to mention this here a year
prior in 2016, my former
grad student Alex G and I we
discovered a small dwarf
galaxy that is currently
orbiting the Milky Way. It's called reticulum, too.
That was full of ancient iron deficient stars that also had a strong signature of these
heavy elements, exactly like 1815-23. We weren't looking for that. I actually wanted to prove that
they had really low levels of heavy elements because that's what we had seen in all the other dwarf galaxies.
And I was dead set on showing yet that that is yet the case again and that that is a typical signature of early star formation.
We already talked about low strontium and barium abundances and the oldest stars, right.
This is what we had seen anecdotally in the ancient dwarf galaxy
that are surrounding us. So that's an ancient dwarf galaxy. That dwarf galaxy has a bunch of ancient stars in it.
Yes. Yes. And so now we find reticulum 2, and it has these, the stars show the signature of
the rapid neutron capture process, the R process, and we are like, okay, these stars are located
in a dwarf galaxy right now. We have environmental information. They are not lost in the galaxy
where we don't know where they actually came from. Now, we know these stars were formed
in that galaxy because they're still in it. And that we already deduced from that, that
it must have been a neutron star merger that went off in reticulum two at early times, that polluted the gas from which all our little stars formed.
Can you speak to what a dwarf galaxy is? Can you speak to what this particular two dwarf
galaxy is that is orbiting the Milky Way galaxy? It's going to be eaten by it presumably
as stuff. It totally is going to be eaten. I can't tell you exactly when. Yeah, the make-away remains
surrounded by dozens of small dwarf galaxies. There are collections of stars.
Some of them, we call them ultra-faint dwarf galaxies because they are now only
contained, I don't know, a few thousand stars. They are very, very faint.
So detectable? Yes, because they're fairly close.
And we detect actual individual stars.
So I've observed some of the fainted stars.
You know, you possibly observe with current telescopes
in these 12 galaxies, because I was like,
I need to know what the chemical composition is,
because there are leftovers from the early universe.
They did not get eaten. So they are still in their native surroundings.
I got, it's like getting the lions in the wild, right?
I got to study those.
Yeah.
And compare to the counterparts that got eaten
and are now in the Milky Way.
And so I...
So presumably most of those stars
is not all those stars in that dwarf galaxy,
they're really ancient.
They're all really ancient
because actually, as it turns out, if you have a small galaxy,
there was a process early on in the universe called reionization that kind of heated up
everything. And together with some supernova explosions in an early shallow, you know,
bound system, all these little systems lost their gas.
It was sort of blown out or it simply evaporated or both, probably both.
And so these systems have been unable to continue to form stars since.
So it's the best for us to allow archaeologists that you could hope for
because it's a whole bunch of stars
still sitting there. It's not just one. It's a whole bunch of them still sitting there ever since
and nothing has literally nothing has happened to them. They've just been waiting there for us.
So from the stellar archaeology perspective, what is like Juicier and more interesting, the
the old stars and the outskirts that have been eaten are the outskirts Milky Way or the stars in the in the Dwarf galaxies.
What's of all the things you love about the world.
You said you love stars, so which do you love more of you?
That's a hard one. I mean, I love them all, of course.
They serve different purposes.
The the
sauce in the make-away, I can get much, much, much better data for them because
they're brighter, they're closer, so they're brighter. And that that tickles my
fancy. And they have interesting kinematics presumably. Yes, and we can get that.
And so H.E. 1523, for example, you know, that one is really bright, only it's a red sign, so it's
intrinsically bright and it's fairly close.
And so the data I got for that was insanely good and that yielded this uranium detection
and thorium detection.
I can never get that kind of data for dwarf galaxy stock.
So that's a big trade off.
But the environmental information that we get along with the basic information
of these stars in each drawer of Galaxy is really, really valuable in establishing, you know, these,
for example, the site information, right? Because the Galaxy is still there, so nothing crazy could
have happened. So it's just to close that loop. Probably some heavy elements come out of supernovae here and there, but
somehow my theory colleagues tell me that the normal supernova just doesn't have enough oomph
to really get that R process going and doing it all. So you need these orbiting supernovae?
We need the probably the neutron star mergers, or we need a special kind of supernova that's
maybe extremely massive or heavily rotating or does something else funny, right, to really kind of get that particular
process going.
But the normal supernovae don't do it, right?
So only a little bit comes up, but you could come along and say, and why don't you just
take 100 supernovae together to build up the yield, right?
But then I come along and say, like, look, this dwarf galaxy is still intact today.
If you would have plugged in 100 supernovae into this little system early on, it would have
blown apart.
It would have blown apart past five supernovae, or 10.
So that's a really important constraint that we have that these systems are still alive.
So it helps us to pin down where certain processes could have possibly happened.
So it's just a different type of information that we get.
It'd be amazing if we could talk about the observational aspect that is the tools of observation.
So what telescopes have you used? Do you use?
And what does the data look like?
I think I've read a few interesting stories about the actual process of day to day observation. A bunch of probably late nights.
Well, yeah, astronomers are doing it all night long. So, yeah, can you explain the all-night
long aspect of it? Well, let me start by saying, I mostly these days use the Magellan telescopes in Chile. They are 6.5 meter telescope, which means the mirror diameter is 6.5 meter.
That's not the largest that this out there, but it's among the largest.
And I use a spectrograph because I'm a spectroscopist.
I don't take pictures.
And that particular spectrograph at that telescope is actually unusually efficient.
So it kind of makes up for the fact that the mirror isn't as large in, let's say, the
8 meter telescopes from the Europeans or so. So I'm very happy with that. Efficiency meaning.
How many photons get collected sort of per time unit because we, that that's always the limiting factor.
Prior to the pandemic, we would travel to Chile to do our observations. Those telescopes are the,
that's the last observatory where people were sort of supposed to travel there and take their own
observations. Most other observatories basically have staff there by now who take the observations for you.
So there's the directly the scientists are specifying where to point the telescope and
the scenario and collecting the data, make sure the data is collected well, the cleaning
of the data, the what offloading of the data, all that kind of stuff.
Yeah, so it's mostly done for them.
Yeah.
Obviously that's super convenient,
but it also takes away a central part
of what the work of an astronomer is,
which is data collection.
Right, we don't have an experiment in the basement
where we can go day and night or whenever we please,
and ask a certain question
of the apparatus, right?
Let's turn this knob and see what happens.
Let's turn that knob and see what happens.
No, you know, we only have one experiment, which is the universe.
And what we see is what we get.
And I think it's so important to take an active role in that.
So I really love going to the observatory.
I've taken many students there over the years to teach them
and to just show them what it means to be an astronomer
because you go to these remote mountain tops
and it's such a magical environment and you wait
there for the sun to go down and then you get ready and you look outside and it's such
a serene environment.
It's a little bit out of this world.
You're sitting there so the sun goes down, it's evening, late evening and what does it look
like?
What are some of the most magical experiences
of that process?
Well, you know, when you're on top of a mountain,
you know, climbers, I guess, get to see that probably.
Otherwise, it's very calm.
And the colors are so beautiful.
And I always become much calmer when I'm there.
I'm just A because I'm just there for one purpose only and that's data collection.
I can say no to my emails, I can say no to everything else because I'm observing.
So there's literally less distractions because you're just there to do one thing.
And also the emails somehow seem less significant. Yeah, yeah. It's just you can't afford to focus on just one thing. And you, it just kind of does something to you. It's a little hard to describe.
But you know, if you then fast forward, maybe I can speak a little bit about that. I have done a lot of astrophotography there as well.
And observing faint dwarf galaxies stars, these are like 45 minutes, 55 minute exposures.
So you actually have a lot of time.
So I would run outside and just lay on the ground under the southern Milky Way.
Beautiful, right up there. And I would just lay there like the
snow angel. And just stare up there and just kind of let my thoughts sort of pass through
my brain and just like, I'm one of it, right? We talked about this in the beginning.
This is when I personally have the feeling that I'm a part of it. I belong here,
rather than feeling kind of small. Yes, I'm small, but there are many other small things, and lots of
small things make one big hole. And we're part of that big hole. And so that's looking at the inner
spirals. Yes. And just, you know, this dark sky with the bright stars.
And I have described this in my book years ago,
if the Mickey way is all bright above you,
you don't need a moon or anything,
you can walk in the starlight and you will find your way.
There are no trees there for safety reasons,
but you wouldn't even run into a tree, right?
I mean, you can almost see the shadow, you know,
from the starlight because it's such a dark side
and the stars are so bright.
And these are kind of moments that kind of change you a little bit.
And it's...
You see the unity of it all.
Yeah, and it's just you and nature and, you know,
with modern civilization and all of that, we often try a little bit too hard to be removed from nature, you know, to be independent of it and figuring it all out, but at the end of the day, we're just a part of it.
And, and that really helps me to remember that, that, you know, well, one in the same.
Well, that fills me with hope that I tend to think of us humans as in the very early days
of whatever the heck we are.
So that makes me think thousands, tens of thousands, hundreds of thousands years from now
that will be reaching, will be, whatever we become will be traveling out there to explore
more and more and more.
So what you're doing is the early days of exploration with the tools we have.
Yes, the early seafarers looking at the sky for navigation.
Coming up with different theories of what's on the other side, that the earth is starting to gain an
intuition that the earth may be around. And then we might be able to navigate all the way around to get to
the financial benefits of getting spices from India, whatever the reason,
whatever the grant, the funding process is all about, but ultimately actually results in a deep understanding
of the mystery that's all around us. And I mean, it's just to travel out there.
I need to meet the discovery of life in the solar system,
I really hope to see that in my lifetime.
Some kind of life, bacteria, something, maybe dead,
because that means there's life everywhere.
And that's just the kind of stuff that might be out there.
All the different environmental conditions,
chemically speaking, that are out there.
And it just seems like when you look at Earth,
life finds a way to survive, to thrive in whatever conditions.
And so maybe that process just kind of humbles you
as a super-exciting to know that there is life out there of different forms.
And of course that raises the question of what is life even?
We tend to have a very human-centric perspective of what is a living organism, and what is intelligence and all this kind of stuff.
And all the work in artificial intelligence now is starting to challenge our ideas of what makes human being special.
And I think we're doing that through all kinds of ways, and I think you're working some part during
that as well. Like the unity you feel is realizing where we're part of this big mechanism of nature,
whatever that is, that's creating all kinds of cool stuff from the humble, pristine
origins to today.
So what is, if you could just kind of linger on the process of the data, what does the
data look like?
And how does the data, the raw data lead to a discovery of an ancient star?
Well, as a spectroscopist, we have to, I guess, talk for a brief moment about what a spectrum
is.
Everyone, I hope, has seen a rainbow on the sky.
That is basically what we're doing.
We don't send the starlight through a raindrop that then gets born around and splits up the light into the rainbow colors.
We do it with a spectrograph, so basically a prism.
So we send the starlight through a prism of sorts and that splits it up.
And then we record exactly that.
So it's a little 2D picture actually of a spectrum. Now it's not
going to look colourful, just black and white, different colours have, of course,
different energies. That's what we record. More specifically, we record it as
wavelengths, so wavelengths and frequency and energies all the same at the end of the day.
We process that little image in a sense that we do a cross cut and then sum up a few columns
so that we get all the data that we recorded.
And what we see is a, it's a bit funny to describe just with words, but a wiggly line with
lots of dips.
So the 2D process spectrum, we call it continuum, so it's just a flat line, basically, and
then there are dips.
So the interesting things are the dips.
If you think back of the rainbow, what we actually see in our stars is not just a rainbow,
but it would be a rainbow with lots of black lines in it,
which means certain little pieces of color have been eaten away by a certain amount.
And so we can no longer see it as well, we're not at all.
Why is that happening? So if we come back to our stars, what we're observing, we're observing
the stellar surface, we can actually never peer with our telescopes inside.
We only ever go, can go after the surface.
And the surface contains, the surface layer contains different kinds of elements.
Every one of those types of atoms, so elements are just different types of atoms, they absorb different
photons that are coming from the hot core where the fusion is occurring. And so that means that if you're the observer, you know, with a spectrograph
or without, you will see the starlight, but certain frequencies, certain energies of that light will have been absorbed by all the different
atoms in the gas. So you see less of them. And so that's other dips. And the strength of the dips
tell us, you know, which element was it? And how much of that element was or is in the star?
element was or is in in the star. So we have many many many dips. The solar spectrum for reference, you know, all the dips are overlapping because the
abundance of all the elements is so high. It's actually very complicated
spectrum. My spectrum really look like a straight line and then there's a
dip here and then the straight lining and it's a dip there. The sun doesn't have
straight lines. I mean, it's just all absorbed in some form or another.
But the old stars have so little off all the elements
that they're only occasionally these dips
that then indicate, okay, that one at that way,
Flings was iron and here we have carbon
and there's magnesium and sodium.
Oh, there's a little strontium line here.
So we have a much easier way to map out this bar code
that the spectrum, you know, pretty much is
at the end of the day.
And to then measure the strength of these,
we call it absorption lines to then calculate
with existing codes that mimic the physics
of the stellar atmosphere,
like how much was absorbed, how many, what kind of elements were present in the stellar atmosphere.
And so this is how we get to our abundance measurements, and then all together that gives us the
chemical composition and that particular signature in that star.
If you, do you ever look at like the raw spectrograph
and the absorption line, and they're able to see
into it some interesting, non-standard outlier kind of patterns?
Or does this have to do heavy amount of processing?
We actually process our, it's fairly straightforward to do our processing.
We do it at the telescope.
So I often take a shorter exposure first, let's say 10 or 15 minutes.
So mostly when I do discovery work, we just take a quick look spectrum, then we process
it while we observe the next star. Then we take a quick look.
We have what I call the summary plot.
It's a collection of little areas in the spectrum
that have the key positions,
the positions of the key elements in it.
And it's kind of like reading the tea leaves.
I have stared at so many spectra.
I just need to know, I just need to see our summary plot
and I can tell you
exactly what the numbers are going to be. And also to tell if it's going to be promising to get
further. Exactly. And so that's it's thumbs up thumbs down. You worth my time. Or not in most cases,
not or it's good enough, we can do a basic analysis, maybe publish this as part of a larger sample,
just so, you know, we output that we have observed this star and they are basic nature that's an
important part to publish as well.
And yeah, I had a run.
So now we do remote observing.
I do all of this now from my home, from my living room all night long.
And I often work with colleagues, so we do it over Zoom. And we process
the data, we look at it same thing still. And we just found a star that had a very low
iron abundance. And then we decided, okay, that looks interesting. We're just going to
keep exposing. So we took more data on it on the spot,
and we're writing up the paper right now.
How do you know where to point the telescope?
It's not random.
There's a lot of work that goes into that.
I began my career by answering, trying to answer that question,
as in like doing the search process.
That's why I called my book that I've written
some time ago, searching for the oldest stars because searching is one thing. It's very time-consuming,
and then on top of that, not everyone finds, right? And I often don't find, but I keep searching
because, you know, techniques have established that, yes, we can do it if we're just patient enough and keep going because it's a numbers game.
And that's often the case in science.
And that's something that not enough is talked about, how tedious it is and how long it takes to get to that one discovery, right, that moves the field further.
And how difficult it is to believe that there is a thing
to be discovered?
Yes, yes.
We have the saying, I learned this, I think,
from my supervisor, one star is a discovery,
two is a sample, and three is a population.
So as soon as you found three of roughly the same
kind, you're done. But you need to get there. Probably the first is the hardest, right?
Yes, but it kind of remains really hard. And but the thing is that at past three, many of us
are like, okay, we solved that problem. We've done it three times, so we can do it. That's
a thing, right? That's a population, three iron deficient stars, let's say, right? That's one puzzle
piece. Now we can move on to the next thing. That's an indicator that there's many more of them.
Yes. Potentially. Yes. Yes. Yes. Yes. So to cut a long story short about the searching,
we started early on with what's called low
resolution spectroscopy of many stars. So for example, my thesis work almost
20 years ago was piggybacking off a quasar survey that had collected. So
quasars are basically giant supermassive black holes that are really far away.
So you only see one big bright light point.
So it looks like a star, but it's actually just a giant
supermassive black hole that outshines its own galaxy.
And people had been trying to study those,
and they had taken little spectra of, you know,
all things in the sky, and it turns out,
oh, you can't fish out the actual stars from that and look for certain signatures that might indicate low-medalicity stars, so stars with low
abundances. And so it was painstaking work to then take medium resolution spectroscopy to get
a little bit more information and to use approximations and to kind of get candidates that we can
then eventually take to the big glass like to kind of get candidates that we can then eventually take
to the big class like Magellan
to get a high resolution spectrum.
So we really see the dips
of all the individual elements
that then give us a final answer
is at yay or nay.
These days with another grad student,
I just I developed a new technique
to use images,
actually, of all the stars in the sky taken with very narrow filters.
So it's like you're wearing very specific glasses that only let so much light
through.
And so we can do similar things through having several narrow band filters,
what we call it, to fish out things that have no absorption
over here, so just the straight line, and then a little dip here, so a little something
there. And that has proven fairly successful in recent years.
So looking at the entire, looking at broader regions of the space.
That's right, because these stars are a little bit like the needle in the haystack, right?
They are not that many left over, and the certain new galaxy has made plenty of stars in between.
We need to comb through all of those to get to the goods.
So we always start with millions, and then work our way down, and in the end we have like
three good candidates.
I wonder how those ancient stars feel that they were noticed.
They probably know that nobody pays attention.
Everything.
I'm just kidding.
We're all special, right?
So all this time.
It's good, it's inspiring.
Even if you're the al-cast.
In your pristine nature, you still might never
let us be noticed.
I'm hoping the same about humans if somebody's observing us.
Is there something else you could say that's about the challenges of this kind of high precision measurement
that you're doing?
So this kind of collection of data, looking, trying to pull out the signal from the noise out there.
Well, that's literally what we're doing in multiple ways actually.
So we're trying to find the needle in the haystack and then we find something and then it
turns out it's just a little bit too faint to actually get the kind of data quality
on it that we would like or that would would be warranted given the potential of the star,
right?
It was like,
uh.
So there's always noise.
There's always a little bit of noise
and you have to try to say like, what, uh,
yeah, how special is this when you're looking
at the absorption line?
Yeah.
So the most iron twostas, their iron lines are so tiny
that they're literally, you know, almost in the noise.
So you need incredibly good data to make detections.
And the funny thing is we're looking for the nothingness
of let's say the iron lines,
but then we don't want nothing
because if there's nothing in the spectrum,
we can't measure anything.
We can only get an upper limit, but we'd really like a measurement.
So we are looking for the last
little bit that you could possibly detect. And that's the strong function of the brightness
of the star because the telescopes have the size that they do that's not going to change
for a while. Hopefully eventually it will, but it's going to be at least 10 years out.
And so yes, we're often literally stuck in the noise because we can't make the measurement.
So actually the record holder for the most iron poster
only has an upper limit.
We can't get enough data on this
to actually pinpoint a measurement,
to then take it to our theory colleagues
and say like give me this little iron
out of your first star.
So it's a bit frustrating,
but also super exciting at the same time.
So let's go to both side of that spectrum.
What's the most exciting discovery to you personally?
Where is there a moment you remember
that you saw a piece of data
and you kind of your heart skipped a bit?
Yeah, yeah, of course.
Is it HEE 1327?
That was definitely one of those moments.
I wasn't actually present at the telescope, but we were sent a data immediately from our
colleague.
And we just looked at it and our eyes got really wide and was like, oh my god, this is
just really what you think it is.
So we had to run some numbers.
And it was.
And these are magical little moments. The thing is, you know, often
we have false positives. And so there's always this kind of period. And often it's, I don't
know, 10, 15 minutes where you need to make some tests to kind of make the decision,
is this really something I should keep observing now? Is this really as good as I think, or am I being fooled by something?
Right? So actually, if you take a spectrum of a wide dwarf, a wide dwarf is the leftover
core of a star like the sun that has gone extinct.
And wide dwarfs have lost all their outer atmosphere.
So it's just a hydrogen helium core.
So they look like a metal porous star because that's only hydrogen helium left, right? But the hydrogen lines that
you can see in the spectrum of stars and of the white dwarfs are a little bit wider
than normal. So you need to have a good eye just to check, you know, does this
look a little bit wider than us? Is this a white dwarf who's fooling me here?
Right? And so it's like this moment. It's like, oh my God.
It's just minutes of nervousness.
Yes, yes.
And sometimes, you know, it's a dud.
And sometimes it's not.
What's been a big day, you remember heartbreak?
Like a painful low point.
Is it all leading up to the first?
Is it all about HE 1327?
Again, just the leading up to it. Or has there
been like, uh, yeah, has there been like low points in the search?
Um, that's a good question. I mean, you know, it starts with mundane things as in like,
you, you want your telescope time, you travel there and the weather is completely cloudy, it rains, and you have three nights,
which is a lot, and you go home empty-handed.
So that's definitely a low point.
Probably not what you were thinking of, but there is a certain occupational hazard to it.
Which requires a kind of resilient person.
Yeah, and you just got to learn to live with it.
Coming back to reticulum too, actually, you know,
that little dwarf galaxy, that was a run that we had
and the weather was incredibly bad.
And I had sent my student there.
And I was at home and he calls me at 2 a.m.
And he was like, I think I observed the wrong stuff.
So sorry.
There is this line
there, this uropium line, and it looks like a metal rich star. And I was like, it's cool. We all
make mistakes. Send me the data. Send me that summary plot. And so I look at it, you know, I was like
super tired. It's like, I can't really tell. It doesn't look wrong, but I can't tell you right now
that it's right either. So why don't you go to the next target? And he calls me back in our later.
Hannah, it looks just the same. What am I supposed to do? And then I joked, well, maybe we found an R process galaxy. Let's go to the next one.
And the weather was degrading.
And so to cut a long story short, we had to come, so he was observing the right stars.
It was an R process galaxy.
The first one we had ever discovered totally un, I mean, un-predicted. We had no idea that this was a thing.
I mean, you know, of course, we thought that, you know, such a thing might possibly exist because
why not? Right? Nuchon Summer just happened somewhere. Crazy supernovae, probably two, but we were not prepared in that moment
to find this thing.
And in the end, the weather was getting worse and worse,
and we wanted to see how many app-resessed
stars are in this galaxy.
So we managed by a hairline to observe the nine brightest stars,
but the data quality was atrocious.
And whether affects the data quality?
Yes, absolutely, because these were really faint stars.
And so we were really lucky by making
a very tight strategy of getting the absolute bare minimum
for all the stars.
So we could at least take a very crude look.
Is it a
yay or a zene? We couldn't even say yes or no. Just just to get an idea because we
needed to know why was that important because we could only observe this
system again nine months later. So there's always a window of observation. Yes. It
was setting. This was our chance and it was going away with the clouds, you know.
That was super high stakes. But we just made it. Really, it was almost impossible.
And it was just the thing is, this is such a serendipitous moment, in a serendipitous moment in a serendipitous moment, the enhancement of these heavy elements was so strong
that even in this really crappy data,
we could still see the enhancement.
The absorption was so strong that it stuck out of the noise,
if that enhancement wouldn't have been as strong,
we would not have been able to say anything
because we wouldn't have been able to tell.
But because it was so extreme, it lends us a hand despite the weather and all to say,
yes, this is it.
So that was quite the night.
Look, a lot of this is just luck.
So that was the first our process of galaxy discovery.
Yes, I didn't sleep all that much. I did.
Do you have hoped?
Are you excited about James Webb Space Telescope and other telescopes in the future that
increased the resolution and the precision of what can be detected out there?
Absolutely.
Data WST is fantastic already.
I am not planning to use it personally, although I think I'm on
one or two observing proposals actually, because similar to what we already spoke about,
we're interested in the same thing. We're just kind of looking at a different
sides of the fence, right? I have my old surviving stars and I concoct these little stories about
what the earliest galaxies may have looked like, what the objects were that contributed energy and elements and all these things.
And my J.W.T. colleagues, they tried to detect some of these earliest photons from these
earliest systems to look at the energetics and other things.
What was there?
How many these kinds of things?
So together,
we're trying to explore this first billion years, but we do it in very complimentary ways.
And so I'm very excited to see what they can come up with and how that helps me to inform
my stories better and more comprehensively.
What do you think is the future of the field of stellar archaeology?
How much can we maybe what are the limits of our understanding of this first billion years of our
universe? Well obviously lots of limitations in the sense that I always say I have a metal
poor star for any of your questions because there are so many different kinds out there.
And we still find new patterns sometimes, right?
And there needs to be an explanation.
The question is, is it ultimately just one quirky star?
Is it two or is it three, right?
Is it a sample?
Is it a population?
So we haven't concluded that kind of work yet.
So every metal poor star is a kind of data point
that you can use to improve the quality of your model of how
Is the evolution of the early universe? Yes. Yes, and I would say we're
We've made huge progress over the last 20 years when I joined that field
It was in its infancy and there was this serendipitous discovery of that first second-generation star and
We have filled in the canvas a great deal since then.
And this is what I have greatly enjoyed about doing so because there was so much discovery potential.
And it's been dying down a little bit because of all the progress. It's going to, it's on the
up and coming again because there's so many large spectroscopic
surveys in the works now that will just provide a different level of data that we haven't
had before.
I'm sort of of these older generation.
I have only very few colleagues.
I work in small teams and I observe every single star myself that, you know, whatever I
can, I do myself. I don't generally take other people's
data, at least not certainly not in the end stage. I'm not a big data kind of person, although
we all headed that way. I certainly use data from the Gaia astrometrics, satellite for the kinematics, for example. But that's
personally a new thing for me to use sort of big sky surveys that are available. So it's
still very sort of hand-grown field, you know, where we do our individual observations.
I have enjoyed that a lot, but that's about to change.
So one start of time. Yes.
I mean, there's power to that to build up intuition of the early
universe by looking one start of time.
Yeah.
And this is how you can really drill down
on the questions that you have, right?
Because you control what data you get.
Otherwise, you have the data that you have, right?
You get what you get, and you don't get upset.
I don't like that. I'm a little
bit snobby. I really like to formulate my questions, go to the telescope and then come what may, I will
try to get it. And also develop the intuition of where the data can be relied upon and where it
can't and all the different quirks of the data and all that kind of stuff. Sometimes a lot is lost
in the aggregation of the noisy data. Yeah, yeah, yeah.
And that's always the danger if you have someone else's data that you just don't really understand
the limitations, completeness things, how certain things were set up.
And you get out what you put in.
So I'm really particular about that.
And it certainly paid off for me.
That's one of the main notions that I try to teach in my classes and to my students,
that you need to be able to formulate your quest question really well,
because otherwise you're going to get an answer to a different question,
but you won't notice that the goalpost has shifted in the meantime, right?
So your interpretation can only be as good as the question. If you need to change your question, that's cool. Do it. But then,
you know, it needs to pair up with your interpretation again. And so knowing, really being in the
know about every step of what happens, that relates to quality results, I think. That's
why I have sometimes little trouble with sort of big data
and statistical analysis. Yes, on average, that's true. I'm not debating that, but I'm the
kind of person I like to look at the outliers, so not the bulk, but the special ones.
And they just need to be treated in a different way, and there needs to be an acknowledgement of
that, different ways for different things. So big data can look at divorce rates and perhaps you and I are more interested in the individual
love stories.
Yes.
That works for me.
So I don't know if it's possible to say, but what do you think is the big discoveries
that are waiting?
Is it on the different dynamics of the yield,
the common narrative, the common story
of how some of these metal poor stars are formed?
Is it where the discoveries in this field that you think
will come?
I think the individual discoveries,
I actually, we've made most of those, certainly through individual
size. Finding yet another second generation size incredibly important for me, but isn't
really going to move the needle. Finding 50 of them or 100 of them, that would move the needle, but that's in order or two magnitudes up. And new search techniques and new surveys may enable that,
but would you still call that a discovery? Right?
So that's just a scale. This is scale.
Yes. So I think about it more like literally of the puzzle,
let's say you have a thousand piece puzzle and you know, you have 900 pieces in
there. If you're a person like me and you know you have 900 pieces in there.
If you're a person like me, I want to get to the last ones.
I'm not going to leave it.
It's like, okay, I see broadly what this is going to look like, right?
I'm done now.
No, I want to get to the last one.
So is the picture globally going to change?
No.
Are we going to figure out all the details and how it really works? Yes.
Right? So really careful detail map out the ancient, the ancient stars of our universe.
Yeah. Because I think that's what many of our scientists have really little bit detailed
obsessed. But I think that's our job too, right? To really kind of make it airtight, to really walk away saying,
I fully understand this.
Not just broadly,
but I really know we really know now.
And so more and more of that is going to happen.
And so I think this is probably true across astronomy.
These individual 10 sigma discoveries
become less and less.
If they were easy, we would have made them already, right?
Which means we have made many of them.
But really filling in the details
is the next sort of level of discovery.
Maybe we need to find a new word for that.
If the hopes and expectations that go along with the word discovery are so enormous.
We may not always be able to live up to that. But it doesn't mean that we're not finding out new
things. It's just a different kind of quality because the questions have shifted. You close one
door, suddenly there are 10 new open doors
that we wanna explore and march through,
and that's finding these last puzzle pieces here and there
that we remake it airtight.
And so there's a lot of value, a lot of power and beauty
to the discovery in the big picture of our universe
and in the details.
So both of us are in the same place.
We need both, absolutely.
Perhaps drifting into the philosophical, let me ask about the big bang as we kind of
encroach onto it.
So your work is kind of taking steps back through time in a weird way.
Do you think we'll get to deeper and deeper understand the really really early days of the
Big Bang?
And the philosophical question, do you think we'll be able to understand what was before
the Big Bang or why the Big Bang happened?
Do you think about that stuff?
Not with stars, for better or for worse, because stars only probe the time when they were formed,
and the big bang is surely before then.
I mean, I often talk to my students about the difference between math and physics.
Let me give you an example.
We talked earlier about HE1523, and I was happy to share with you that I met a thorium
in uranium, but I actually didn't quite close that loop.
So we did this to try to attempt to calculate an age for these stars.
Right?
But they rely on us knowing how the R process works, how these elements are created, where it happens,
and then how those elements get dispersed into the gas and end up in the next generation star.
So quite a few question marks. So that's how we got to the age of 13.2 billion years.
This is probably not accurate, but this is the best calculation we could do.
And the reason why I'm bringing this up is that that was actually the average of multiple
elemental ratios that each gave a certain age. And then we average that because And the reason why I'm bringing this up is that that was actually the average of multiple
elemental ratios that each gave a certain age.
And then we average that because for better or for worse, this is the best we can do.
So some of these numbers said, oh, this star is 15 billion years old.
And then others said, oh, this is 10 billion years old.
And so I often use that in my class to say like, what's the good news and what's
the bad news here? Some ratios say 15, something 10, right? Is 15 correct? And then I asked
them and some people will say something. And so the thing here is that it's an absolutely
correct calculation given the mathematical and physical model that
we constructed. But does it make sense? No, it doesn't. If we believe the universe is 13.8
billion years old, 15 is ridiculous, yet it is correct. Isn't that interesting?
Correct from a mathematics perspective. It is not incorrect because this is what I calculated.
Nobody made a mistake.
Now, we can question whether that's a good model, but that's that's a separate issue.
So you're saying physicists are much closer to truth than mathematicians?
Well, it depends. Sometimes yes and sometimes no.
Right? So what our job as physicists is to take the mathematical model,
calculate our numbers, and then ask the question,
does this make sense? Right? Now, in the case of 15, it doesn't, but we took the average anyway,
because that was the best we could do. Right? So, all right, let's put that aside, let's apply
the same sort of thinking to the Big Bang, right? Math can tell us things that we as physicists
cannot grasp because it doesn't make sense to us. Now, in the case of the Big Bang, that's
a special case because we don't actually know what's supposed to make sense. And this
is where things get interesting, but this is where math will ultimately be the winner,
because we can no longer say this makes sense or this doesn't make sense because
the physics is broken down.
But math breaks down too in the singularity of things.
Well, depending on who you ask.
Okay.
Sure, sure.
This is the current question, right?
How far, how much further can we push math, let's say, to the front of the big bang, if
there is such a thing?
What's the front in the back? What's the front? the front of the big bang, if there is such a thing.
What's the front in the back?
What's the front? The front is the big bang.
Oh, before the big bang.
The front.
Okay.
Super.
Right.
We all the doorways in the entrance.
So how far can we let the math go before that stops to make sense?
Right.
And I don't know what the answer is to that.
But it's really cool that because math doesn't have, it's not limited by of physical nature, it can probably go
a little bit further than the physics. Yeah. Right. And math can go into more dimensions than
four dimensions comfortably. And it's, it's judgment free because it just calculates things on
its own. Whereas as physicists, we're so judgmental.
This makes sense. This doesn't make sense. It doesn't get any worse.
It's such a beautiful dance. It's so amazing that through this dance, you can explore the
origin of the universe. This is in the big bang just blow your mind, that this thing is just started from a point.
Now we're here.
Yeah, yeah.
Hydrogen and helium.
And then all the stuff you're studying, I mean, this evolution of chemistry created
humans.
And we're here talking.
And there's a lot more to the story.
It's amazing.
And this kind of march that you're doing is observing data.
Is there, you're looking at old light, old data.
But only a few thousand years, right?
Just a few thousand years.
That's the difference between me and my JWT colleagues.
Their objects, that light has traveled 13 billion years,
whatever it was, to us, and they're observing that now.
My light has only traveled a few thousand years.
It's nothing.
So whatever you observe now is likely still going on.
Yes. These stars are alive and kicking and having a blast.
Thousand years.
Just a few thousand years, it all it takes.
If we can travel close to the speed of light,
maybe we can reach out there.
We wouldn't have any planets around those stars though.
So is that a definitive intuition?
Well, what are planets made of?
Elements, right? To take the Earth planets made of? Elements, right?
To take the Earth.
It was all heavy elements, right?
The universe needed to reach a certain stage first
to have produced enough of all these elements
to actually make a planet.
So on average, you're, so, okay, right?
So that took quite a few billion years.
So they're not going to have a mechanism
for forming planets.
You could have visitors probably,
but the kinematics
of that are unlikely. Yeah, I would say so. Okay. So they're interesting in that they reveal
the early chemical evolution of the universe. Yes. Not that there could be good vacation spots,
but not. Well, there's not a warm. No, worm. No. No planet islands to go to chill.
In your book, you highlight the major contributions in the field by many women.
Some of these women were not as you described immediately credited for their discoveries.
So from me, from computer science perspective,
the story also tells Harvard computers,
who were these women and what can you just say
about the nature of science and humanity?
Discovering things is part of the human nature, right?
And so it has happened for the longest time,
not just by men, but also by many women. The field of Stella astronomy,
which is my field, has particularly benefited from many discoveries made by women.
You mentioned the Harvard computers. That's a term used for women who worked about 100 years ago at the Harvard College Observatory, and they
were hired for their low wages and willingness to do diligent and patient work to comb through
the big data of the day.
So the observatory director, they were carrying out large
sky service at the time and they needed that data needed to be processed
and looked at and analyzed.
And so many women or several dozens or one or two dozen women over the years
were higher to do this work.
And in the process, because they were looking at the actual data and they were smart, even
though they had often no formal education, they made a lot of discoveries simply by being
in tune with what they were doing.
So they were on robots as, you know the the term computer would perhaps
let on lead on. So any jump cannon classified thousands and thousands of spectra and found out
that you can you know stars have different temperatures and their spectra look according. We still use that classification sequence today.
Cecilia Penda Poshkin, later on in, I think, 1925, was one of the first women to obtain
a PhD in stellar astronomy.
And she figured out, she calculated that the Sun is mostly made of hydrogen and helium.
That seems normal to many of us these days, but at the time, it was thought that celestial objects are made of the same thing as the Earth.
That's a gutsy, amazing discovery. Yes.
It was later termed the most important thesis of humankind or something like that.
What a revelation to realize that stars are made of hydrogen and helium, right?
And this was exactly the time when people figured out why stars are shining, namely because
of nuclear fusion, and that it's protons
and the tunneling effect that leads to the actual fusion.
Otherwise, the protons repulse each other.
They don't come together.
And so what an incredible time it was back then.
And so stars and nuclear physics were very closely related.
And it remains that now it's called nuclear astrophysics.
And so many women had many contributions to that, of course, prior to that, Marie Curie,
discovered two new elements. Ah, so awesome. Radium and Polonium,
radium and polonium, Liza Maithna discovered nuclear fission.
That is the basis for understanding the R process.
This is exactly what happens in the R process.
The heavy nuclei, let's say uranium,
if you bombarded with a neutron,
we talked at length about it.
It will decay, it will not decay actually.
It will fition, it will split into barium and krypton,
let's say, so two lighter elements.
That's exactly what we observe.
I have always a higher abundance of barium
than the heavier elements because of this fishen cycling
that she calculated in 1938, 1939.
So many, many contributions and it's just so remarkable. If you just take that body of work, that changed how we do things, how we see the universe, how we understand
things, has led to so many subsequent discoveries, good ones and bad.
Well, we did all of it, it's taken together, it's all about it.
That's progress, right?
It's, it's, it's science is what it is.
We have to decide what we do with that knowledge, right?
We can always use things for good or for bad.
That's, that's part of the human endeavor as well.
And also part of the human endeavor
and the human nature is the issues with corruption
and credit assignment and all these kinds of things.
They make this whole ride so damn interesting.
What's right and wrong and about the nature of good and evil.
And that seems to surface itself
in all kinds of places all the time.
Yes, yes.
Lisa Meintner was nominated for the Nobel Prize 40 times more than that.
It's amazing.
She holds the record for that.
She never received it.
So, Kisenpointer.
Yeah.
And of course, the Nobel Prize is as complex as it is.
One is the credit assignment, but two, even an astronomy,
sort of assigning credit to a handful of folks, was so many more contributed as a complicated story.
Also. Yes, very complex. Okay, so I have for the romantic question, but what to use the most
beautiful idea in astronomy, in stellar astronomy? Well, so early on, you know, when I was in high school, I was thinking like, okay, what do
I want to do when I grow up, right?
I knew I wanted to do astronomy, but I was a little bit torn because my interests were definitely
stars, stellar astronomy, but also chemistry.
I always had a fascination about the elements.
So Marie Curie was a big role model.
My friend actually made a beautiful, produced a beautiful movie about the discovery of
the elements. This is a theater play, but digitized.
Where when I saw it, I could actually kind of relive the sort of discovery moment that
Marie Curie had.
It sent chivers down my spine.
It was fantastic.
I mean, this is the kind of thing that I wanted to experience.
But yeah, so nuclear physics and element creation information was really interesting to me, chemistry,
the element stars and all of that.
And I was like, I don't know if I ever find something that combines all of these things.
And then I ended up in Australia and I met this person and he was working on old stars.
And as I was sitting in his talk, hearing about this for the first time,
it kind of, it clicked all over my head and was like, oh my God, it all fell in place
because we can use these old stars to study the elements, to learn how they're formed.
We can get these clean signatures that help us inform the nuclear synthesis processes,
you know, and I know, of course, I need to know a lot about stars too.
So it's like all together.
And that was sort of a moment of magic.
And then the fact that I have now done that for 20 years,
it's just like, I won the lottery.
It all clicked into place.
And so in some sense, it's an ongoing love story for me.
If I could say it like that where you know I found my stars
my thing and I'm fortunate enough to be able to keep doing that and I'm happy to
see where where it will take me you know it's an evolution as with every relationship you have to
if you don't march forward you move backwards backwards. I'm not interested moving backwards.
So I'm letting the field and the discoveries and the findings lead me to, you know, I'm often,
it's not hard for me to follow sort of my hunches and sometimes even at the tellers,
go up and say, hmm, let's take a look at this one.
I have a good feeling. And then usually something good or, you know, not bad. and sometimes even at the tellers, Cobb and Snack, hmm, let's take a look at this one.
I have a good feeling, and then usually something good,
or you know, not bad, pops out at the end.
And I really like that,
a. That I have the freedom to do that,
that I'm allowed to follow my hunches.
Too many people, I think, are sort of boxed in
with their job or their life.
They don't have that kind of freedom.
That's really important to me. And I certainly try to make use of that. I also try to teach that to others.
To trust them, to learn, you need to learn your things, but then you need to also trust that knowledge.
And then you have a grasp on it, right? You get out what you put in. And being able to contribute in meaningful ways to our knowledge about our
cosmic ancestry or cosmic history, that's a wonderful thing. And in this way, your personal love
story with the stars evolves, what advice you've already spoken to it a little bit, but
what advice would you give to young people that are trying to find the same kind of love
story in their career and their life?
It seems increasing the hard for folks to find that. Sometimes I feel that young people have all the opportunities these days, and that's wonderful,
but it's almost like that leads to some, what's the right word, they're a little bit of tired,
of too tired to make all the decisions because at some point you need to put your eggs in a basket,
and you need to be okay with that. We can't do all the things, even though
we're often told you can be president too. And I think that's really important to convey.
But at the end of the day, we can only have sort of one job or one type of profession.
I'm not saying, you know, you need to be locked in, but it's hard to change 180 degrees.
to change 180 degrees. And so lots of people I think are often afraid to really dig in, at least for some time and get the hands real dirty and really learn from the bottom up.
On one thing.
On one thing, because they're afraid they're missing out on 99 other things. But life is a little bit missing out on 99 other things
because we only have 24 hours in the day.
I have that feeling very often.
There are so many things I would like to do.
Many things I would like to try to be good at.
Sometimes I wish I had a different job,
because I have other interests too,
but I realize, okay, I can only do one thing.
So I have other interests too, but I realize, okay, I can only do one thing. So I have no regrets.
But this is a general feeling that I think I would think most of us have.
But if it stops you from really digging, drilling down on one thing,
to become an expert and one thing, to become really good at one thing,
that you call your own, then that just makes a difficult.
And so a fulfilling life is in part likely to be discovered in a singular
pursuit of a thing of one thing. Well, yeah, for at least for a time.
Yeah, for some time, with your heart and your hands, because I think most people long to own something.
You know, we all, I think, want to leave some legacy of some sorts, you know, for our children, for humanity, for this planet.
And I think it's really important for young people to strive for that and not lose sight or trade that for all the opportunities because
an opportunity is nothing if you don't do anything. You need to do something at the
end of the day. So I chat with lots of people about this and I often start by just saying,
hey tell me what you don't like. It's often much easier to narrow down. Yeah, narrow down. Let out what's not on your plate.
And then this way we get a little bit closer.
And then I was like, well, why don't you take a risk?
And just sign up for something for three months.
But that's what it feels like.
That's what it feels like.
And it is that.
It's a risk.
Commitment is a risk.
Yes.
Because it's your basic sacrifice
and all the other possible options.
But then I guess you have to trust the magic you noticed in that thing. Yes.
You notice one thing, just stick with it.
And then maybe there's something there. Right, right.
And this moment of kind of feeling it in your entire body and mind that
this is the right thing, you know, getting there is probably really
hard. But if you don't try, you won't find out.
The hard stuff is the fun stuff. That's also another thing you find out.
And then there's that, yes. Somehow, it doesn't make sense. You also mentioned that you've
taken a little stroll into the artistic representation of yourself. Can you speak to that for a little bit?
Yes, well, I already just mentioned.
Sometimes I wish I had more time to do other things.
So I find little sideways, I guess,
to pursue things that I like besides astronomy,
or at least I try to find connections.
So some years ago, I, again, with the help of my friend who made this Marie Curie movie,
she and I wrote a one woman play where I actually portray Lisa Maidna,
who was an Austrian-German physicist from Germany,
so I have the right accent for that.
And we wrote this play about this moment of discovery
of nuclear fission.
Again, this is an absolutely critical piece
that explains my work today.
And we all stand on the shoulder of giants.
She was one of those giants.
And in some ways, it's, of course, a way for me
to acknowledge other people's work that have come before me.
It's a wonderful way to highlight the contribution
by a prominent woman.
And the way I do it is it's a 25-minute play in costume where I
relive for people the moment of discovery. Then I turn into myself and then I give a 30-minute
presentation on the art process and the creation of heavy elements
because the audience can now perfectly understand
that the public audience,
given the historic backdrop of this discovery
that they just lived through my presentation.
And it's a wonderful compliment
that almost spends 100 years from one woman
to the next passing on the torch.
And when we write up our results in,
let's say, magazines like Nature and Science,
it's always about the result.
On the golden platter, perfectly prepared,
the discovery is never described, only ever the results.
You ask me beforehand, right?
What does it feel to be at the telescope in this moment, right?
I'm happy to talk about this, but it's no way I've written never.
Nobody, nobody really talks about it.
And so having a form of, you know, theater of the arts
to bring this, this exciting moment that, that is what
we all want to experience as scientists to a wider audience is so profound and so rewarding
and they all love it because everyone can understand a moment of discovery.
I was looking for something and then I found it.
It's like you misplaced car keys, right? Or love. Yes, yes. Everyone can understand.
What are the glorious experiences? Yes.
The implications and the findings that is much harder to understand for anyone. This is
where the scientists work truly lies. This is our job, but the moment of discovery is easy. And it's
beautiful. And it needs to be said. And so taking my audience on this journey, what is the
perils? What are my worries? And then, ah, here is the moment of discovery. Let me tell you about
it. It profoundly transformed me. And here, here's how it went, right? It's so good.
And art is a way to reveal this fundamental human side of science. Yes, it's the problem
with science is that it's people doing it. That's also the problem, but that's also what
makes it beautiful, right? Humans are fascinating and they were able to come up with these ideas through all the struggle,
through all the hardship, through all the hope, through all the search.
And so the art is a great way to portray that and to broadcast that, right?
I think this is how the audience really should be interacting with scientists, much less about
the findings, but really more about this yearning for answers, right?
I need to find these
khakis. I need it because I need to go. It's like now, now. And then, oh god, here it is. Now I can go
my Maryways. It's so relatable. We just need to find more and better ways to do that. So I hope to
turn this into also a digitized version at some point to again
make it more accessible. I hope so too. So far I'm just doing it in person.
But it's I would love it. I think a lot of people would love to see it. So I hope you do just that.
Let me ask you a big ridiculous question. You look up at the stars. You look up at the early,
early early stars. So let me ask the early, early, early stars.
So let me ask the big question that we humans often ask and struggle to answer. What's the meaning of
this whole thing? Why are we here? We talked about, you know, the biological evolution requires
the chemical evolution for all of this to kind of play out and carbon played this important role. And in some sense we're just a consequence of all
of these things being the way they are, right? So maybe this is just where we
are supposed to be because the loss of physics sort of worked the way they do
and we talked much about the variety of everything really in
certainly, you know, from over here to over there and things in the vicinity of
where the sun and the solar system formed, they were the way they were and life
maybe wasn't necessary consequence of that. In some sense I like to believe that because then it becomes reproducible and we can apply
that same argument elsewhere.
If it's total chance, right, that makes it harder.
That's not truly satisfying to a scientist.
So it's a consequence of psychological evolution, which is a consequence of biological
evolution, which is a consequence of chemical evolution, consequence of physical evolution, which is the consequence of biological evolution, which is the consequence of chemical evolution, consequence of physical evolution, whatever, whatever disciplines, it's turtles on top of turtles.
Turtles all the way down, yes.
I, yeah, I would have studied some of the most ancient turtles.
Yes, yes.
At the very bottom of the thing.
That's right, at the time. They live for quite a while.
Yes, they do. Well, thank you for your
incredible work. Thank you for highlighting both the human side and the deep scientific
side. It's just a huge family work and thank you for everything you do. I thank you
for talking today. This was awesome. Of course, it was wonderful. Thank you.
Thanks for listening to this conversation with Anna Frabel. To support this podcast, please check out our sponsors in the description.
And now, let me leave you with some words from Douglas Adams in Hitchhike's Guide to
the Galaxy.
Far out in the uncharted backwaters of the unfashionable end of the Western Sproulal
arm of the Galaxy lies a small unregarded yellow sun.
Orbiting this at a distance of roughly 92 million miles is an utterly insignificant little
blue-green planet whose ape descent and life forms are so amazingly primitive that they
still think that digital watches are a pretty neat idea.
Thank you for listening.
I hope to see you next time. you