StarTalk Radio - Vera Rubin Observatory with Zeljko Ivezic
Episode Date: July 29, 2025Will the Rubin Observatory prove Einstein wrong? Neil deGrasse Tyson & Chuck Nice answer queries about the new observatory, the Legacy Survey of Space and Time (LSST), and our next big tool to uncover... the universe with Zeljko Ivezic, Director of Rubin Observatory Construction.NOTE: StarTalk+ Patrons can listen to this entire episode commercial-free here: https://startalkmedia.com/show/vera-rubin-observatory-with-zeljko-ivezic/Thanks to our Patrons Ceil Hook, Travis Cowger, Mitaka, Tonatiuh Mielto, Henry Holzgrefe, Jr. , Seth Price, Kimberly Christian, Cynthia McCarty, Hector Bojorquez, Jan Groenteman, jesse riley, Brian Borho, Tori Levine, Emily Rice, Janet Andrews, Matthew Murphy, Ara Rice, Kyle Lewis, Brandon Anderson, Michelle, Kevin Ahern, Jason VanNimwegen(N7IAG), Johnny K, Joshua Barkley, Nathaniel Randell, Jon Waterfield, Matthew Schrage, Zdravko Iskrev, Norman Weizer, Brad Magic Soace, Alfrdo Fettucine Jr, Larry Taylor, Kelli Buckle, Darkarma, Lillian S., Jay Swami, Niki Anderson, Stephen Sullivan, Prasad Mohire, Dylan S, Billy Maher, Andrius Linkus, Jack Terpstra, Jason Duran, Christopher Tuomi, Farrukh Baig, Carlas, Margaret Widman Dees, and Sister Peace for supporting us this week. Subscribe to SiriusXM Podcasts+ to listen to new episodes of StarTalk Radio ad-free and a whole week early.Start a free trial now on Apple Podcasts or by visiting siriusxm.com/podcastsplus.
Transcript
Discussion (0)
So, Chuck, we brought the whole room into Reservatory for an episode.
Yes, we did.
They fit in one chair.
The entire team, 400 people, right here, right now.
Coming up on StarTalk.
Welcome to StarTalk.
Your place in the universe where science and pop culture collide.
StarTalk begins right now.
This is StarTalk.
Neil deGrasse Tyson, you're a personal astrophysicist.
Got with me, Chuck Knight.
Check it, baby.
Hey, what's happening, Neil?
All right.
Yeah.
Well, good.
Today's your birthday.
Oh.
Oh.
It is.
Today.
Yes.
Yeah, it was a day that will live in infamy for my parents.
Okay.
And you're 29 today.
Yeah, exactly.
Forever 29.
Yeah.
Forever.
Yes.
So recently we did a what's up with that on the recent release from the Rubin Observatory.
Okay.
That amazing swath of data that came out.
Right.
And we said that we got to do more than just me reciting what I learned.
Oh.
Let's get people from.
Let's go straight to the source.
Let's get straight to the source.
Right to the source.
And so the person who conducted.
that press conference
we've got them right here
sitting right there
you'll have to correct me five times
with your
authentically Croatian name
Zelko
Zelko
I got to put my face in it
Zerka
Zelko
Avisich
Perfect, welcome to Start Talk
Thank you
Thank you for inviting Rubin team to the show
Yes and you flew in from
Udub
University of Washington
in Seattle, Seattle, Washington.
So thanks for coming to New York
into my office here at the Hayden Planetarium.
It's quite some office.
It actually looks like a science hoarder lives here.
No, I'm just the receiver of many science gifts.
That's a different thing.
It's a big difference.
Yeah, yeah, yeah.
So we are talking about the LSST,
which in its earliest incarnation,
because I was on the Decadal Survey,
that sort of made sure this went into motion.
This is now back 15 years ago.
Back then it was called the Large Synoptic Survey Telescope.
And even then I said, no, we can't have this.
And so even that got rebranded as the...
Vera Rubin Observatory.
Yes, but then you swap new words.
And there is still LSST.
I know, but you swapped new words.
Correct.
Now it's legacy survey of space and time.
That's the project we will undertake during first 10 years.
It's a data set.
They did better there.
That's so much better.
A legacy survey of space and time.
That's badass.
Yeah, that's badass.
That sounds like it could be like part of a movie.
You know what I mean?
There is a tiny problem with that, though.
It's very hard to translate it to some languages like Spanish or Croatian,
where you talk about legacy.
People think you died unless something you have.
Oh, yeah.
In English, it's perfect.
Yeah.
Yeah, okay.
Very important there.
And I named after Vera Rubin, who was an astrophysicist.
knew her. And she visited Princeton often when I was there. And I think we first met at Princeton
during your... Thanks to Robert Lapton and Michael Strauss. Yeah, two two key components of the astrophysics
landscape in the Princeton campus. Yes. And so she was a big observer of galaxies and try to figure out
what stars were doing within them,
discovering dark matter.
She and her colleagues,
Kent Ford, one of her collaborators.
They did great measurements
that were very simple to interpret
and very convincing
that there is something
fishy with gravity.
So with this telescope,
and your role in this,
what I have you down here,
you're the director of the construction project.
Oh my gosh.
I still am. A few more months.
I still am.
So there was still getting
refined and built and tested.
By and large we are done, but now we are fine-tuning the system.
It's a very complex system, especially the software.
So we are learning how to optimize it.
And then in a few months, in October, probably, we'll be done with construction, and then we turn it on.
And it's effectively a robotic telescope, robotic observatory.
We are not going to think every evening, like, let me look at this, let me look at that.
That's the old days.
It would have to be.
In the old days, yeah.
So what I think people need to appreciate it.
if they don't already, is that modern observations
are more about the data pipeline
that comes from the detector more than it is
just what you're going to do with the telescope.
Right.
I mean...
Exactly.
And so, can anyone apply for time on this telescope,
or does this telescope already have an agenda
that it's going to accomplish?
We have a very strong agenda, and it's very simple.
We want to scan the sky as quickly as we can.
Basically, we can cover the sky every three, four nights,
and we want to do it over and over and over relentlessly for 10 years.
Every single night.
Every single night.
If it's clear.
So it's like, like, you know, my father was a printer and in the dark room,
that's the time is the development.
So is that kind of the problem?
Because you say it's the same sky over and over and over.
I can only assume that you're layering image over image over image to get more and more light
that gives you better, better, deeper, deeper.
Oh, no, no.
It can do that, but that's not the point.
No, get out.
It's one of the two points.
No, Chuck is right.
Chuck is right.
You add many images together and you see more and more objects.
Okay.
You can see deeper, deeper and deeper.
And Neil is right too.
Because we want to look what changed between these different...
Ah, well, that is even more key.
That's right.
I gotcha.
Because any ordinary telescope can just stack images.
Right.
And what you're really doing when you're stacking images, there's a noise level in the background,
the visual noise.
And every next image you stack, it tamps down the noise.
But if there's a signal there, the signal gets boosted.
the signal gets boosted.
Nice, right?
It's nice.
So the noise drops, the signal goes up.
And the signal to noise ratio, as we say, goes up.
And so you're going to get that regardless,
but the real contribution to this landscape of data
is you're making a movie of the night sky.
That's amazing.
You guys are like the early days of Walt Disney,
but for observatories.
It's a much bigger movie.
We call it the greatest movie
because it would take you about a year
to look at every frame that we will obtain.
Wow, you guys actually beat out Jesus for the greatest story ever told.
All right, I'm leaving.
You guys are finding you know astronomy.
Protect Chuck from himself here.
What fraction of the nights do you expect to be completely clear?
About 300 nights per year.
Not too bad.
Not too bad.
Wow.
Not too bad.
And, of course, the sky shifts a little bit each night.
And so in December, you're not getting the same sky you're getting in June.
Correct.
How long is your movie that you will have?
So the movie will be 10 years long.
Now, some parts of the sky, you always have heard.
That is a serious director's cut.
Directors, they don't leave nothing on the floor.
Exactly.
like 10 years.
10 years.
It's going to be 60 petabytes of data.
60,000 terabytes.
Yeah.
It's mind-boggling.
Okay, but I guess what I want to understand is,
for any given spot on the sky,
you have continual coverage
not for 10 years.
You have it for six months.
Well, some parts.
Yeah.
Some parts close to the pole, you see.
You see continuous.
And some parts that are closer to the equator,
we will have like five months, six months, seven months.
That's the point.
Right, so if you're near the pole, we call those circumpolar stars.
Right.
They never rise and they never sat.
Right.
Because the pole stars above the horizon and the stars just go around.
Yeah, yeah, yeah.
And so throughout the night, you get it the whole time.
Right.
So in 10 years, we'll see each object about 1,000 times.
And for some objects, it will be uniformly distributed over 10 years.
For some, there will be clumps of like six months, and then a few months no observations.
And then again, a few months of observations.
Suppose something happens when you're not looking.
Tough.
I like it.
That's the way to cookie crumble.
That's the right attitude.
No, it's very frank.
But you'll also catch me, a lot of them.
Right, right.
So what are the high points of expectation?
Well, let me say that differently.
For objects very far away, galaxies,
if a star goes bump in the night, you'll see it,
if they have a supernova or a nova, all right?
But those are too far away for you to see anything moving.
So there you're checking for changes in the brightness of an object
whereas much nearby you're looking for movement of objects
such as asteroids.
Asteroids or stars in our Milky Way.
They move too, but much slower than asteroids.
So you really need to wait for 10 years to reliably see that motion
of stars that go around the center of our galaxy.
We are going with them.
And so we can see relative motion.
With asteroids, you look at it and within half an hour
you are definitely certain that there is motion.
It seems to me your biggest contribution
to the astronomical data sets
that we currently have
will be in the discovery and tracking of asteroids.
That's one of the four pillars that we have.
So it's studying the solar system, asteroids.
Then the other one is studying the Milky Way,
stars in the Milky Way,
about close to 20 billion stars,
more than living people on Earth.
Then we want to study cosmology,
We want to look at galaxies and supernovae, to try to decipher why do we see accelerated expansion
of the universe.
There are basically two ways to explain it today.
One is to postulate Einstein's theory of gravity is correct, which leads you to conclusion
that there is some mysterious fluid called dark energy, of which we know nothing.
The other possibility is that Einstein was wrong, and theory of gravity is wrong, and we need
to fix it.
And people already proposed many different ways to fix it.
But we don't know which one of these two is more correct or less wrong.
And we don't know it now because we don't have data.
I'm betting on Einstein.
It's not a bad bet.
Just coming in blind.
I'm going to say the Vegas odds are like, you know, six to five on Einstein.
But yeah.
Yeah.
So let me just get a layman's perspective here.
When you talk about dark energy, that is the pressure that is speeding up the expansion of the universe.
What are you looking for that demonstrates that?
There are several ways to do it.
So supernovae, of course, play a major role.
They directly measure the expansion.
They tell us acceleration.
But then to get handle on gravity,
you have to look at the effects of gravity.
One of them is the formation of structure in the universe.
When you look at galaxies on the sky,
they are not randomly distributed.
Like take a handful of sand or salt throw on your table.
There is not much structure.
But when you look at galaxies on the sky,
They have these clumps, and then they are voids where there are no galaxies.
We want to measure this very precisely.
That's one way to do it.
The other way is so-called gravitational lensing that goes back to Einstein,
where light is curved because of mass.
And so by looking at that curvature, which distorts images of galaxies,
we can tell how much hidden mass there is.
And so all these together...
So your dark matter will also curve the light, even if you can't see the matter at all.
So you need many different probes to decouple these different things.
influences. And so we know that in order to make the next scientific step, we need to measure
about 10 billion galaxies. And you just can't do it with existing observatories. You could,
but it would take a thousand years, thousand years. We'll do it in 10 years with this new
observatory. So you're able to do that because what, you have like a wider field of view?
Yeah. Correct. You think? How much bigger is your field of view in one snapshot, can I
you sway that.
How much big your field of view
than that of the Hubble telescope?
Oh, interesting.
It's about
thousand times bigger.
Oh, my God.
So typical telescope sees
and part of the sky
that is much smaller than full moon.
And in our field of view,
you could fit 45 times the full moon.
Oh, wow.
It's much larger.
So if Hubble were to do this,
they would have to sit there
and take one picture here and one there
and then mosaic it all together
and get the big picture.
And by the time that's had,
you know, we're all dead by then.
Yeah, yeah.
Yeah. So this is like the introduction of panoramic view on the camera phones when it first came out.
Exactly. You know, everything was like, they were like, oh man, you don't have to take a picture here, pay here, hair, pair, paper.
I like analogy with tiles in your bathroom. If you want to put new tiles, you could use Roman mosaic, those inch by inch, it would take your whole weekend to do it.
But if you go home depot, you get this good American big tiles, you go slap, slap, slap, and you're done in half an hour.
That's a great announcement.
I need to get on to your next topic.
Right, right.
That's funny.
But I still like to think that what it's doing compared to previous images is way more than just your panorama setting on your iPhone.
On an iPhone?
Just a little bit.
Just a little bit more than that.
Instead of taking five pictures, I take one, we're talking thousands.
Right, right.
And so this, of course, you have this huge camera and detector.
That's a big, beautiful camera.
Big, big.
Big, beautiful camera.
3,000 megapixels.
That's the biggest, the biggest camera.
And what we're trying to figure out is how it can take a picture of me.
I'm Ali Khan Hemorrhage, and I support StarTalk on Patreon.
This is StarTalk with Neil deGrasse Tyson.
So it seems to mean that some of the public will be very much interested in dark matter, dark energy,
because it's a big mystery and we all love mysteries.
Other parts of the public
might want to know more about those asteroids
because we've all seen asteroid movies
where an asteroid comes our way
and Bruce Willis
and the odd thing is
holding aside that the movie Armageddon
violated more laws of physics
per minute than any other movie ever made
the scenario that an asteroid could be headed towards
Earth is one that has precedent on Earth.
Right.
Okay.
That's a movie that actually would be a rerun.
Oh, really?
It's already happened.
That's already happened.
So, in terms of, I don't want to say national security, global security, you will have
better data than any Air Force, Navy, Army data could possibly accumulate on the risk factors
of Earth getting hit by an asteroid.
So do you have a relationship with the military?
with the military on this?
Or Bruce Willis?
We don't.
So if we had a relationship, it would be with NASA,
their planetary defense office.
But because the nature of our data
is to look at everything on the sky,
these potentially hazardous asteroids
will be like gravy on top of everything.
We don't have to do anything special to find them.
Oh, they come in for free.
And because the system is so powerful,
we will indeed be the most powerful machine
for finding new asteroids in general
and potentially hazardous asteroids in particular.
What are you saying?
The men in black haven't shown up yet.
Exactly.
They're going to show up.
That's funny.
So I caught you on that press conference
just a few weeks ago
and brilliantly executed
and very excited.
I was just pizza delivery guy.
At the end of a great supply chain,
he had fantastic team
that produced all those great images
and videos.
And they had their day in the sun there
or day in the media,
which is good and important, of course,
because you work
most of your life.
It was an awesome day after 20 years of working hard on this.
Yes.
To see thousands of newspapers and thousands of TV stations pick up our images.
And that's an authentic interest.
They were not bribed to attend your press conference.
Exactly.
So what intrigued me most about all the data?
Because I've seen pretty pictures of nebulae before.
And you zoomed in, you zoom in better than anybody else.
Okay.
But excuse me, after it was it 10 hours, there's thousands of,
previously undocumented
asteroids showing up
in your data? Thousands of them?
Thousands. We discovered more than
2,000 in just a few nights of 2,000.
Wait, and a few nights of 2000.
You identified all these asteroids, none of which
are in any catalog. Well, correct.
That's out of control.
There are about million known asteroids
now, and in first few years with
LSS we'll discover 5 million more.
So we'll increase
the number of asteroids by factor of
compared to last 200 years of people discovering us.
That's technology.
That's rapid development of technology.
It's not because we're smarter.
It's because...
We'd love to say we are so much smarter than our forefathers.
It's because of technology.
Yeah.
Yeah, the first asteroid, you know when the first asteroid was discovered?
No.
1801, I think it was.
Wow, that's...
That recently?
Yes.
Well, after Galileo and Newton and...
Oh, yeah.
All those guys looking up before then, you would have thought.
Had no idea.
No idea.
Right.
Oh, look at that.
Yeah, yeah.
So is there people tasked especially for the asteroids?
We do have a group that keeps an eye on it, but it's all done by software.
Got it, of course.
So what role does AI play in this?
To assess whether what we discover actually makes sense.
So it's all done automatically.
AI comes in many places in our observatory from running the observatory
to decide where on the sky you're going to look at to interpretation of images,
classification of objects and such.
Probably one of the best things AI does, period, is pattern recognition.
So I would assume that all these changes that you're looking for,
that's going to be a big part of what the AI does.
Absolutely.
There will be so many objects, as I said, billions, more than living people on Earth.
So you really need them to be able to notice one tiny change among billions of them.
And that's where AI comes in.
We couldn't do that without AI.
Okay, so it's noticing a change.
Now, do you anticipate discovering a kind of object that has no known precedent?
Every project prior to us, every project that was breaking technological barriers, that
was at the cutting edge, every project discovered something they did not expect.
In the history of science.
In history of astronomy, in science in general, yes, yes.
So we think we will discover something super exciting, but I can't tell you what.
We call it unknown, unknown.
but our power to look at the sky, to see what's changing on the sky,
power to measure things more precisely than anything else before,
that is what gives us confidence.
We'll find something super cool.
So more precisely, you're referring to the resolution of the image.
It's resolution, its sensitivity, the amount of data,
relentless scanning of the night after every few nights,
of the sky after every few nights.
That's what gives us confidence.
I don't mean to value judge what you're putting together there,
but for me, the least interesting objects
would be the variable stars.
Because we've had variable stars.
Tell me again what a variable star is.
It varies in its brightness.
Ah, gotcha.
That's how we roll in the National Service.
Yeah, you just, what it is, where I am is what you call me.
There is American Association of Variable Star Observes.
Who don't like you right now.
They don't like you right now.
Okay.
It'll feed them their breakfast, lunch, and dinner, like forever now.
Just that most stars vary at some level.
You're going to find variations that...
Even the sun varies.
Yes, exactly.
So at some level, every star is variable.
And so if every star is variable...
Then no star is actually variable.
Then variability is not a designation.
It's not a big deal.
If we all vary, then...
It's like if everybody's special.
If everybody's special.
Then nobody's special.
So what kind of stars would...
be especially interesting in the variable star category?
I think interesting events are when there is some microlensing with planets,
then we can see that star has a planet, so we'll get some of those.
But we'll have hundreds of millions of variable stars,
because we'll have 20 billion stars overall.
So it's like totally new ballgame.
We are changing it from millions to hundreds of millions.
It's like someone increased your salary by factor of hundred.
Would you live differently?
Yeah, that would probably live differently.
Yeah.
So is there any, because you bought up Hubble just a minute ago, I mean a little while ago.
So when we look at the detail that Hubble came out with, are there any areas that you might find where you'll just put it over to them?
Like, hey, you should look at this.
Or does that not make a difference?
Are there telescopes that would be interested in follow-up measurements with whatever is their specialty,
which could be different from your telescope special?
Absolutely.
That's one of the goals.
Either in wavelength or this, because Chuck was trying to inquire about that.
Yeah.
Fun fact.
When we get a new image in Chile with this observatory, it's shipped to California for processing
within few seconds.
Within 60 seconds, that image will be compared by computers to all the previous images we obtained
from that part of the sky.
Everything that is new in that image, it changed in motion, it changed in brightness.
We will report to everyone in the world who is interested in.
the world who is interested within 60 seconds
and every single telescope
in the world should they wish so, can go and do
follow-up.
You know, that is
gangster.
In my day, in my day,
my day, we had to actually
look through a piece of glass.
We actually had to be night time.
In my day, if someone discovers
something, we're very organized,
my people. We
got each other's back. If someone
discover something at a telescope.
Back in the day, they'd sent out a telegram.
And there is this special telegram
service just for us. Just for you guys?
Okay? And it would show up in the observer. And before
you went observing that night, you'd check
to see, is there a star that just blew up?
Is there something that just moved?
Is something? And if it can fit into your program,
you would get, you would
part your own observing program
to get data on that object. And then you send it
back to them.
Well, that's...
And, and...
and you're observing the object
you're monitoring the object
but then the sun rises
for you
not for that guy over there
not five six hours over in time zone
and they can pick up the observation
all through telegrams
so you should be able to do that right
absolutely so Hawaii is the first
place with telescopes that comes on after
Chile then you go to Asia
then you go Europe Africa you come back to Chile
so we have
the sun never sets in the Rubin Universe
that's very cool
That's very cool.
Now, do you guys also use telegram?
But he did use the word ship.
He said, it ships to California.
Right.
Ship.
I'm thinking of, you know, Spanish galleons.
But, yeah.
Good evening, Mr. and Mrs. America, and all the astrophysicists who see.
Dateline.
We have a new image.
Okay.
We now have fiber optical cables going from South America to U.S.
Oh, wow.
To redundant cables.
But when SDSS., previous big astronomical survey.
The Sloan Digital Sky Survey.
I remember going with a doof bag full of DLT tapes
from New Mexico to Princeton carrying this data.
Duffel bag.
Duffel bag. What did they say?
You said doof bag.
Oh, a duffel bag, could be heard differently.
A dup bag is a bag full of stupid, Peter.
Cut it out.
A bag full of doofs.
Yeah.
So it would be physically carried.
Correct.
Yeah, I remember we would compare back when Ben
width was narrow, and speeds were, you know, low board rate, we had to calculate,
do I send this through over the computer, this early 90s, late 80s, or do I put it on a disk
and send it by FedEx?
Right.
Okay, so there's the bandwidth of FedEx.
Wow.
And now it travels at the speed of light.
Close.
Well, yeah, it's fiber optic.
I mean, Verizon says it's the speed of light.
We have to divide by the index of refraction of the glass.
That's right.
I understand because it slows down light.
It's a medium that slows down light itself.
I got you.
I remember that.
We did a thing on that.
I think we did a little.
Yeah, we did a whole thing on that.
All the different mediums through which light actually slows down.
But technically, light always goes at the speed of light.
Right.
Because it's light.
It's light.
Exactly.
You know how fast you were going there, sir?
I'm light.
Yeah, I was going to me.
So, you know, the photon checks into a hotel?
Okay.
And the bellhop says, do you have any luggage?
The phone time says, no, I'm traveling light.
We have queries for this episode.
Oh, I forgot.
This was so good.
I forgot we actually had people.
I didn't forget.
This is a cosmic query.
It's for the Ruben Telescope.
I should get them ready.
With the man himself.
I should get them ready.
Yeah.
So we have a fan base and a subset of the fan base actually pays monthly to participate
in ways they have little extra benefits.
One of them is they get to ask questions at the entry level.
You got questions here?
I do.
I have them ready to go.
Here we go.
All right.
Let's start off with Hugo Dart,
who says,
Hello, Dr. Tyson and Ivisich, and Lord Nice.
This is Hugo Dart from Rio de Janeiro, Brazil,
with my seven-year-old daughter, Olivia,
who was a big fan of StarTalk.
That means she's asking all the questions.
Exactly.
Not him.
Right.
Here is...
The grown-ups try to sound so smart, but it's their kids who...
The kids who actually know the deal.
Yeah.
Here is our question, public access and open data are key principles of the Rubin Observatory.
Good.
How do you envision citizen scientists, educators, and students, using this data and what tools are being given to develop and support them?
We all heard or read that all the data will be made available to people, essentially, instantly.
So everyone can participate in this.
So what are the plans for that?
And I like that.
What tools?
Because you can't just say, here's the data.
You know, they have to know how to get into the data.
Are there, is there a tandem set of tools to support the citizen?
Now, Rubin Observatory and LSST are not just for scientists.
They are for everyone.
And we have a large suite of tools that you can use to get to our data.
A couple of weeks ago, you could see that thing called Sky Viewer,
that allows you to zoom in, zoom out, enjoy the night sky.
But we'll have many other tools on top of that.
And Hugo is asking.
minutes, sir. You're telling me, people will no longer have to look up because they can see the sky looking down on their iPad because you brought the sky down here. Now no one's going to look up because of you.
Yeah, but you can't see what you can see down there up there with you. You can always look up.
You can take a laptop or an iPad. You look up, right? That's great. You got me there. Okay. So you have a suite of tools. And where do we find those?
tools. You go to Ruben Observatory.org and all the links there. Actually, there is already ongoing
citizen science project with Comets. My colleague, Colleen, Orion Chandler, from University of Washington
just started a few days ago. They already have hundreds of thousands of images processed by
human eyes. I forget how many thousands of people in the first week of that project are already
enjoying Rubin data. So these are people looking for comets? They are looking at things that move. And the
question is, does it look wider than star? Do you see any evidence that it's a comet and not
nasty? With fuzz. With fuzz. Right, right. Because an asteroid is just a dot of light on your
frame. And stars are dots of light on those same photos. So when Herschel saw them, he said,
this kind of looks like a star, but it's not. Right. Because it's really nearby and it's moving.
So it's star-like. Asteroid. Nice. Asteroid. That's where we get that name.
But if you have AI finding everything,
how can a human being actually participate in this?
With AI, you need training sample.
And so training sample has to be as similar as possible
to what you're actually doing.
And we are just starting now our projects.
So now we are getting people to help us make a training sample.
And then we will use training sample to train AI
that will do it automatically.
Interesting.
So these people are helping a lot
to deploy AI later.
You know, he talked about looking for fuzz
so you can find the comet.
The inverse of that happened,
fascinating research paper
by William Herschel.
William Herschel.
Okay, he's looking at the night sky
and he sees an object move.
Okay?
Right.
And he said,
it must be a comet.
Before asteroids were discovered.
Right.
It must be a comet.
He keeps watching it.
And there's no fuzz
on the comet.
Right.
And he says, this is an odd comet.
And he published a paper, an account of a peculiar comet.
And he said, it refuses to show fuzz.
Right.
The man discovered planet Uranus.
Wow.
He discovered, but he was in denial because no one had discovered a planet before.
Right.
So why would he think he's discovering a planet when everyone has discovered comets before?
We had comets forever.
Okay.
So that's a funny inverse problem here where there was no fuzz, therefore it was a planet.
Are you going to be able to find Planet 9 if it's out there?
Do you think?
If anyone will find it, it will be Rubin Observatory.
Nine's getting cocky.
If it exists, and if it's in the right part of the sky,
and if it's large enough, we have the best chance of discovering it.
But there's no guarantee we will.
That's badass.
That is pretty cool.
That's like, if it's out there, no one else will get it before we will.
The answers are out there, Scully.
there are many previous projects that looked hard
and so they said that they are at sensitivity level
they didn't find anything
and now we are pushing the sensitivity
so I'm not being cocky
I'm just stating the fact
it's not cocky
when you're right
exactly
yeah I'm not being cocky
if we all know that I can kick your ass
that's just the facts of the situation
so great so remind me
what is the latitude of this observatory
minus 30
So you can go
circumpolar to the south pole
But you'll be missing a cap
In the sky in the north
We will
And what fraction of the total sky
Will you never be able to observe
Never ever about one quarter
But our highest quality map of the sky
And movie of the sky will be for half the sky
Half the sky
Okay
So this calls for
A twin of your observatory in the north
There you go.
It would be hard to justify it in scientific terms
because we'll get most of science done with just half the sky
because of statistical effects and so on.
But it would be fantastic to have another one in the north, I agree.
Unless the asteroid is coming from the north,
then he won't miss that one.
Yeah, I mean, yeah, I'd like to have eight.
Like, four north, four south, and then at different lungingness.
Yeah, then it's continual.
Exactly.
Wow, that's...
Then no killer asteroid could escape.
We catch them all.
Kets them all.
Unless they're peculiar
comes from the direction of the sun,
but there is medicine for that too.
Plus, as we move around the sun,
you can't always stay behind the sun
unless it's being intentionally hidden there.
Well, that's aliens.
At that point.
There are some interesting asteroids
that go around the sun in orbit similar to Earth's orbit,
takes almost a year for them,
about a year to go around.
But there on the other.
side of the sun. So for us to see them, they're basically hiding behind the sun. So sometimes
takes 20, 30 years for them to move enough for us to detect them. And we just learned, and we
did a little explainer on it, how Venus can hide asteroids in two Lagrange points that orbit
with Venus. But Venus is always near the sun. Venus is never the opposite direction because
it's interior to us. So if it's got asteroids that are hidden there, we will never see it because
they're lost in the sun's glare right and if they get like nudged the pop out of their orbit they're
a risk factor yeah yeah yeah i don't want any asteroid come to us without your warning first
bill do sir that's that yeah this is my finger not that it will make much of a difference we can't
even pay for a warning system for floods i don't just so i'm not going there right right this is james
Liggett. And he says, hi, y'all. This is Jim Liggett from Midland, Texas. Midland, Odesset.
That's a twin city there. So the place where the wounded warriors parade got hit by a train.
I don't know what that means. But he says, what wavelengths of light does the telescope see?
And what is the reason for that choice? Good question. Let's start with just human vision.
Can you see all the wavelengths that the human eye can see? Yes, we can. So from 0.4 to 0.7 microns, we see.
Everything that eyes can see, but we see more, a little bit more.
Okay, so now you got that.
So now keep going.
Now you go towards shorter wavelengths towards Ultra-Iallet.
And there we go...
Just on the other side of Ireland.
So it's cut off by the atmosphere.
And so we see everything you can if you're on the ground.
And then on the other side towards near infrared,
we go all the way to the sensitivity of silicon, roughly 1.1 micron.
The CCD chip, its sensitivity drops off after a certain wavelength.
But you got it right up to that.
Exactly.
Okay.
So we are doing as well as we can from the ground, unless we use different detectors.
If you want to go into shorter wavelengths than UV, you have to launch telescope above the atmosphere.
Right.
So why don't we put Vera Rubin Telescope in space?
There are two basic reasons.
Our data throughput is so large that we couldn't downlink some of the energy.
And it would be very, very expensive.
Right.
Right.
Well, so, I mean, I said that almost jokingly, but one can imagine.
a future where you would build Ruben Telescope on the moon.
You could.
Oh, that makes sense.
Then it's still sort of, it's got a ground base.
It's got a ground base structure.
Yeah.
Yeah.
It's certainly technologically possible.
Right.
It's all about funding for it and justification.
Oh, is that what it's only about funding?
Is that all?
Well, there you have it.
Yep.
It'll never happen.
So what other telescope in the world at another country comes close to Rubin?
The closest one, so you need to have large telescope.
large field of view and camera to support it.
So the one that is the closest
is Japanese Subaru telescope
with hyper-sub-prime camera on it
and the telescope is cited in Hawaii.
Okay, and that telescope's been around
a few decades, if I remember correctly.
Right, right.
So they refurbished with a new camera.
Right.
And so if they spend all their time
using that camera to scan the sky,
so they would be about at one-tenth of our speed,
be about 10 times faster than them, but they are not using all the time for that program.
So we have close to 100 times faster than our competition.
Okay, so one can say that the United States leads the world right now in this way.
And so going in the future, it's a matter of do we want to keep leading the world?
Because we have a lot of innovative ideas that are on the docket.
You know, this is not the only great idea telescope anybody's ever had.
Right.
And so I'd be interesting to see going forward how we value our leadership in these areas in the United States.
So, and allow me to say that from beginning in the 20th century,
the United States has prioritized leading the world in astrophysical observations of the universe.
We've had biggest telescopes like forever, right?
Correct.
Yeah.
And so you make the biggest telescopes, you get all the data.
And then he'd say, okay, now we have a technology that can make an even bigger telescope.
And bigger is better.
Well, it makes sense.
That's how to get more light and more data.
That's how that goes.
Maybe that's the way we can get funding.
Just keep telling people that it's the biggest.
I do believe that today we need more coordination between different nations around the globe
because these instruments are becoming more and more expensive.
Right.
So the plain competition, where you make two of the same thing and try to compete them, that makes no sense.
Right.
So why not allow people to concentrate on different areas, different technological advances, and then share the information?
Exactly.
Yeah.
Well, everybody does what they do best, and you make the one amalgam from it.
Right.
Yeah.
Yeah, that makes sense.
And our project shows nicely where United States is very strong.
That's software.
That's new algorithms.
that's this new technology.
The reason why Google and Facebook and Amazon is in this state
is this huge base of people who are great at software,
historically and today.
And our project was enabled by these great expertise
in software domain in computer science in United States.
And that's what we don't want to fall behind.
Absolutely.
I have a book here called Cosmic Discovery, written by Martin Harwit.
It came out 45 years ago,
but he made the point.
There's a follow-on to that a few years later.
He made the point that we can dream up whatever we want in the universe,
but at the end of the day, the technology that enables it
is what creates the leaps and bounds in our discoveries.
Absolutely.
Right up and down, up and down the stack.
So, you go for it.
Give me another one.
You just gave the next question.
Okay.
This is Yogg who says, hey, quick question.
We use telescopes to reserve the universe, but are they enough?
what else do we need to truly monitor the cosmos
and have we even identified everything required to do that?
So are telescopes the only game in town?
Is that all we really have if we want to look out into the universe?
Or are there other things that we might be able to utilize
to augment or add to that?
As Neil already pointed out, we don't see the whole sky.
And we see it only during night, not during the day.
So it would be great to have at least two, maybe eight,
similar observatories,
then there are different wavelengths,
and so you want to get some instruments
above the ground. That's, for example,
another fantastic U.S. project, Nancy
Grace Roman, yes.
Telescope, which will be fantastic,
also a huge field of view, above the atmosphere,
sensitive to different wavelengths,
longer infrared wavelengths, that will give
you a different kind of information about the universe,
then we can get from the ground with Rubin.
So together, these two will be a great
complementary missions.
And kind of today, wouldn't
longer limited to thinking only about electromagnetic energy, light, because we have the gravitational
wave observatory. How about neutrino? We have neutrino. Both of these we are going to try
to get electromagnetic counterparts if they trigger us. We do have, you ask earlier, are we always
going to just do the same thing over and over? It's true at the 98% level, but we reserve about
2% of observing time to interrupt what we are doing. If there is a great trigger coming from LIGO or
from Ice Cube Observatory.
Ice Cube is the neutrino observatory embedded in Antarctica.
Right.
So a few times a year, they'll tell us something interesting happen.
New gravitational wave source.
Go and find what is the counterpart.
And you could easily donate or forfeit, what's the way.
You can easily allocate a short amount of time to get some good data.
And then you go back to your continued movie.
Yeah.
Again, that's more of the, more of the, we got each other's back on this.
Yeah, very, very good.
The only people more collaborative than scientists are rappers.
If you do on my album, I got a very right album coming out.
So just let me just emphasize what you just said so casually.
We make an observation in any one of these domains that,
so gravitational waves, neutrinos, and who else knows what else might come down the pipe.
these would be coming from
extraordinary phenomena in the universe
colliding pulsars
whatever
and not all of the data
arrive at Earth at exactly the same moment
so what gets here first
is it the gravitational waves that's moving
at the speed of light
all right neutrinos
and then neutrinos come a little later
a little bit later just a little bit later
tiny then electromagnetic
part photons they could come
much later because there is
sometimes needed for this energy
it to get through the local environment to produce the emission that we would see okay so you can
just watch that happen and now you now everybody's got a piece of the action and you bring it together
and we can then describe this animal that is an elephant that would otherwise be unthinkable
and electromagnetic part lasts longer so even if you don't catch it at the beginning yeah you can
still get very useful data that will inform me about what's going on right so it's not just a
Fuzzy tail and toenails and tusks in a trunk.
Somebody can know that we're looking at an elephant.
That's wild.
This is Holly Sweet.
That's a great name.
That's a great name.
Okay, that's good.
Hello, Dr. Tyson, Dr. Ivisich, and Lord Nice.
I was wondering, during the building process, when the telescope is installed in the observatory, is up and running.
How do you keep everything clean and pristine to prevent foreign objects from interfering with your research?
Thank you, Holly Sweet, from Mount Holly, North Carolina.
All right.
All right.
So it took some effort.
It's a great question.
It took some effort to clean the observatory after construction.
Right.
That's true for any construction site.
There's construction dust and the like.
But here it's especially sensitive.
And what we care about the most is our mirror, which is very sensitive.
And indeed, even though we are trying to protect the dome where the mirror is,
every few years, we will need to recode the mirror with a thin layer of silver to
make it shiny again.
It loses its shininess.
Right.
Is it a solid mirror or segments?
It's a solid mirror.
And how what's the diameter?
8.4 meters is the outer diameter.
It's actually two mirrors in one.
It's like one disk that has two optical figures.
The outer one is the primary mirror.
And then inside the inner 5.4 meters is a different optical figure that acts as tertiary
mirror.
Oh my gosh.
It's a very unique optical design that allows us to have very large field of hue.
large field of hue without very strong distortions.
Right.
Wow.
So, Holly, the answer is sham-wow.
That's what they used to clean things.
Oh, shammy.
Shammy, chamois.
Is there a spider mount for a secondary?
Correct.
There is.
Okay, so you will get diffraction spikes.
We will, four of them.
Because you know all those pictures that show the spikes?
Right.
Because it's an artifact of the detector, of the system.
Yeah, it's not the actual star going...
That's right.
Right.
Yeah.
Yeah, it's not an actual thing.
It's kind of like lens flare.
Yeah, yeah, yeah.
This is Louis Gabriel Thibald, and he says, or Tibol, Tibol.
He says, Dr. Tyson, Lord Anise and Dr. Iva Zich, this is Louis Gabriel Teebo.
Did you get it right, Chuck?
Yeah, I did.
How about that?
Louis.
He said down, okay?
People rude, people so, people get, Chuck don't get no respect.
They come from me, man.
He says, from Quebec, Canada, straight north of New York.
What was the construction risk that came closest to impacting this project,
and what did you do to avoid it?
So were there any risk factors that you almost,
realized that could have placed the project in jeopardy or at least delayed it.
And I'm trying to picture this.
How do you move an eight-meter mirror into place?
What road do you travel that on?
Or is it carried vertically?
And if it's vertically, what happens if wind comes?
Or did you build the mirror on location?
These are all fantastic questions.
We had many risks.
Fortunately, we either mitigated them or they didn't materialize.
we carried mirror in horizontal position.
There is a tunnel when you go up the summit where the observatory is.
From Las Serena in Chile, you take a road for an hour, public road,
then you go to ORA compound.
ORA is the Association of Universities for Research in Astronomy,
which is an association of about 50 universities and other institutions.
And it's funded by the National Science Foundation.
Yes, by and NASA too.
And it's a federal funding from US.
And the tunnel is just a couple of inches wider.
than the mirror.
So it took hours
to go through a few hundred yards.
Two inch through the tunnel.
Man, I would hate to be the dude
driving that truck.
I do not want that job.
Where's the top half of the mirror?
Well, we left it at the...
Oh my gosh.
Wow.
That poor person, whoever they were,
they had to be dying.
What would you have done if it was not wide enough?
Probably hire a helicopter
and just take it up there,
but it's much riskier operation,
much more expensive operation.
Plus, helicopters are less good at high elevation?
Yes.
Because they need lift.
They don't have as much stuff to push against.
Right, right.
You need like turbo helicopters and things.
Oh, man.
Oh, man, I'm just, I'm still feeling bad for that driver.
Just waiting to hear the sound.
Just like, oh.
Plus nowadays mirrors are pretty thin, right?
What's the thickness of this mirror?
Depends what you count.
But if you look at the support, too,
Then it's maybe foot and a half something.
Oh, even that thick.
Okay, so it's not a flexible mirror.
It is flexible, but it's got a honeycomb structure.
And then we have 150, I think, six pistons underneath.
That's what I was wondering.
That's called the active optic system that deform the mirror.
The mirror gets deformed by gravity as you point to different parts of the sky.
And then these pistons, again, make a perfect figure to get the sharpest possible image.
Wow, that is really.
And it does it like 10 times per second.
It's like crazy.
You look at the image, you calculate where you need to push it, pull it,
and you do it 10 times per second.
So this fixes the gravitational distortion of the glass,
but do you also have adaptive optics?
We don't, because you can't have such a large field of view
and adaptive optics.
You can make adaptive optics work over maybe a few centimeters field of you,
but not like two feet of glass.
Okay, so the Keck Telescope will still have value
to an observation you might make
with its adaptive optics,
it might be able to see more detail than you can.
Absolutely. It could be great follow-up instruments.
Great follow-up. Good. Okay.
Wow.
All right. Great question. Time for a couple more.
Stephen Schultz, who says,
hello from the birthplace of aviation.
Steven Schultz here.
Wait, birthplace of aviation.
That would have to be Kitty Hawk.
Yeah, I guess so.
We're North Carolina.
Does he say?
No, he says first off...
We just have to know.
Yeah.
He knew what he was doing when he did that.
First off, thank you, Dr. Tyson.
for digitally, diligently working to spark people's curiosities for the cosmos.
What all needs to go into consideration when deciding where to build a telescope of this magnitude?
So why that location?
Why Chile?
Right.
So first you want to go to a place like Chile.
You want to go high.
The Andes Mountains goes the complete length of Chile.
So he'd say go to Chile, you got mountains galore.
That particular location, like that peak, was part of that aura property that is already developed.
There is a road.
Then there is SOAR telescope.
And then there is SOA-R.
S-O-A-R.
Yes, that's an acronym.
Yeah.
And then there is CTIO, which stands for Cerro Tololo, Inter-American Observatory, which is half an hour away from our site.
That's why I got all my thesis data was from CTIO.
Oh, very nice.
I'd be known in the Chile, you know, multiple times.
So there is this aura-supported infrastructure, including roads.
and other observatories that provide infrastructure.
So that kept the cost down.
You didn't have to build the road.
Exactly.
And level out a new mountain top.
And because other telescopes are active there,
there's good statistics on what observing conditions you can expect.
We knew it was very dark sight.
It's important. There are no lights polluting your background.
And we knew that we had many clear nights per year.
And the atmosphere was very stable, so our images are very sharp.
Like if you wanted to go, say, to Kitt Peak, Arizona, that is also a storied place to observe,
it's not as good in terms of darkness because they are nearby big cities.
Tucson, Arizona, I think, is right nearby.
And then it's not as good in terms of atmospheric stability.
We get better image quality in Chile.
Is that because you're off the ocean and there's a certain layers?
Its combination, geography, ocean and Andes together.
Yeah.
Oh, wow. Yeah, you're like shielded on one side and then the ocean, I mean.
Well, this is stability.
I mean, this is how why Hawaii does so well, right?
Exactly, very similar.
Yeah.
So, it's laminar flow, I think, instead of turbulent flow.
Canary islands do.
Oh, I forgot about them, yes, of course.
Oh, very cool.
All right.
Well, that was a good question.
Thanks, Stephen Schultz.
Chuck, I think we had time for one more.
All righty.
How about Chris Ayala, who says,
dearest Dr. Tyson, Lord Nice, and Dr. Ivisich, Chris Ayala from New Jersey.
here and my question is
what are your
greatest fears and aspirations
for this project
going forward?
That is a great question.
Yeah.
Let's start with fears
so we end up on good note
with aspirations.
Okay, good, good, you know.
And by the way, if something breaks
next year, is it your fault?
Next year, it will be fault
of my colleague called Bob Lum.
He will be new director.
Whoever is the director
at the time.
Like the French king said,
flood after me or something like that.
Okay, all right.
So let's hope that doesn't happen.
But yes, if we broke mirror,
you cannot just go to a grocery store,
get new one.
You have to wait for years.
You can't even go to Home Depot.
You can't go Home Depot.
It's something that is not offshore.
What would break the mirror?
Something falls onto it.
Maybe we try to maintain something
and we are not careful.
And there are not many examples
in astronomy where people broke mirror
and especially not large mirrors.
There are very complicated procedures
where every step is prescribed like ballet.
You just don't go there and do what you want.
It's already pre-established.
But sometimes there's a risk that you don't know was a risk.
That's how they decide when they put in a traffic light
on a country road.
You do it after there's been accidents.
Exactly.
Because the stop sign didn't work.
Camera is the largest camera in the world.
Very complex.
And there are things that can go wrong with it.
Right.
Maybe it's vacuum, it's cooling, and things like this.
you cannot guarantee that it's right you cool the chip we have to cool the chip to like
minus hundred centigrade otherwise it would detect itself yeah it would look like uh i mean people
from your generation you know you remember those old TVs when there was no and yeah that's how
our images would look like yeah it would just be all noise if you didn't cool it down okay so
so and that would be fundamental to the flow of the data stream if that okay then there is also
So possibility that we don't get funding to operate it, but I'm not going there.
I'm going to switch to aspirations.
Yes, okay.
So aspirations are that we first, that we fulfill everything we promised, all the science
projects, from cosmology to hazardous asteroids, that we deliver on what we've been
saying for two decades, we will deliver.
Then next, that we will have some unknown, unknown, exciting result that will be perhaps
even more exciting than everything else that we plan for.
That would be like a great super thing to have.
And let me insert there, is there a serendipity mode
either in the software or in the targeting
where, kind of like when Hubble, the director of the Hubble Institute
said, let's point it to a random place.
There's nothing there.
Just see what happens. See what happens.
We talked about it, we just didn't call it, that it's target of opportunity
observations for LIGO, four neutrinos, those 2%.
That's when we interrupt what we are doing.
And we do something different.
But because we scan the sky every few nights over and over and over,
serendipity will come by itself because you basically look at everything on the sky.
Of course.
Wow.
That's, he said it.
Because any normal telescope, typical telescope, you have an observing plan because you already know what you want to look at.
Right.
Because I already predetermined this is interesting.
That means I'm not looking at this thing.
I don't know if it's interesting, but I know this is interesting.
And this goes undetected, unexplored.
But when you're looking at everything, you don't have that problem.
You don't have that problem.
That's pretty cool.
That's really cool.
Oh, yeah.
Well, this is an opportunity to say, for all of our listeners, this is where you have to call your senator and tell them, do not defund science.
Do not take money away from science.
You're not giving us any money in the first place.
so it's not like there's a lot to take away
so just leave it alone
so that we can continue doing these type of projects
that actually are for the benefit of all mankind
and the entire globe
and our future as a species
so yeah
keep your grubby little hands off of our science money
there you have.
Lord nice, I love you.
Suppose you don't like
money getting spent on art or on science. These are frivolous activities done by people who are
the fringes of society. I suppose you could do that. You can create a country that allocates
no money to the creativity expressed in art, the creativity expressed in science, or other
exploits of human curiosity. You could do that. But think about it. Is that a country
you would want to live in.
A country with
no art,
no science,
no discovery of any kind,
no cosmic discovery?
Holding aside that we might discover an asteroid
that would render us extinct,
seems to me we'd want to know about that.
Seems to me.
But how about the rest of the splendor
and the glory of the universe
brought to us by frontier telescopes?
Not only on Earth, but in space.
This is an activity, as old as what it has been to be human, to look up and wonder what is our place in this universe.
I don't know anyone who has not looked up and thought that or felt it.
Nobody looks down and has those thoughts.
It's by looking up.
I'm imagining if you're in Congress.
And they say, why should we fund science?
What value does it play in national defense?
or the art projects that you have in mind
or anything else
that's just a pure expression of human curiosity
in this world
my only answer
would be Senator
it creates a country
worth defending
and that is a cosmic perspective
well thank you for being on StarTalk
thank you again for inviting Rubin
oh that's your new name now Rubin
it's my team
it's a great it's like you don't talk to me you're talking to the whole team and everybody who
in a collective effort yeah okay the greatest astronomical discovery machine ever built and nobody can say
anything greatest movie of all time no you just went tom brady on us yeah yeah i mean you know
it's a fun fact yeah some people call me the greatest of all time but i mean like i don't have to
i just let other people do that
rubin is michael jordan of astronomy there you go thank you guys yeah so dr avertich thank you for
flying all the way here to New York
for this from Udub
Seattle, Washington.
All right. Chuck, always good to have you, man.
Always a pleasure.
All right. As always, I bid you
to keep looking up.
Thank you.