StarTalk Radio - Cosmic Queries – X-ray Astrophysics
Episode Date: April 5, 2019Vote now for StarTalk to win a Webby Award! wbby.co/vote-pod18Explore more than the eye can see as Neil deGrasse Tyson, comic co-host Chuck Nice, and Kimberly Arcand, Visualization and Emerging Techno...logy Lead for NASA's Chandra X-ray Observatory, answer fan-submitted questions to uncover the X-ray universe and beyond.NOTE: StarTalk All-Access subscribers can watch or listen to this entire episode commercial-free here: https://www.startalkradio.net/all-access/cosmic-queries-x-ray-astrophysics/Photo Credit: X-ray: NASA/CXC/Univ. Potsdam/L. Oskinova, et al.; Optical: NASA/STScI; Infrared: NASA/JPL-Caltech. Subscribe to SiriusXM Podcasts+ on Apple Podcasts to listen to new episodes ad-free and a whole week early.
Transcript
Discussion (0)
From the American Museum of Natural History in New York City,
and beaming out across all of space and time,
this is StarTalk, where science and pop culture collide.
This is StarTalk. I'm your host, Neil deGrasse Tyson, your personal astrophysicist. And today, it's a Cosmic Queries X-ray Imaging Astrophysics Edition.
You didn't think we had one of those, did you?
Well, we did, because we have one of the world's experts in that very subject sitting with me right now.
I've got with me Kim Arcand. Kim, welcome. Thank you. I'm going to get your title correct here.
It's a long one. It's Visualization and Emerging Technology Lead for the Chandra X-Ray Observatory.
Yes. Wonderful. And they didn't just pull you out of the ether. You've got some chops.
I'm holding your book called Magnitude, Scale of the Universe.
And I love this.
On the cover, it's got a mouse, a human brain, a bowling ball, a hot air balloon, and Earth.
It's like, what scales are they?
And you open the book, and it lays that stuff out.
And it talks about when things are big and small and how to think about them relative to one another.
This is stuff we confront every day in modern astrophysics.
Cool.
How do you wrap your head around the scale of things?
And you need a visualizer to know how to do it best because otherwise we fumble ourselves trying to explain it.
And so, beautiful book.
Thank you.
And my co-host, Chuck.
Hey, Neil.
How are you? Welcome back to StarTalk. Absolutely. It's a pleasure, yes. Thank you. And my co-host, Chuck. Hey, Neil. How are you?
Welcome back to StarTalk.
Absolutely.
It's a pleasure.
Yes.
All right.
And you're tweeting at ChuckNiceComic.
Yes.
And you're Instagramming at?
Kimberly Cowell.
Kimberly?
Cowell.
K-O-W-A-L.
It's my maiden name.
Just had to throw that one in there.
Why you got to do that?
It's an old from an old Yahoo email.
Don't ask.
Oh, okay.
So Kimberly Cowell.
Kimberly Cowell.
Okay.
But since you're a visual person, Instagram, you got some kick-ass images.
I do love Instagram.
Yes.
Yeah.
So we're going to all look for that.
That'd be fun.
Yeah.
So you got some questions for us, Jack.
Absolutely.
Let's do this.
Yes.
You know, we have, of course, solicited questions from all over the interwebs.
And we've got some good ones here, but we always start with a Patreon patron.
Because Patreon patrons give us money.
Oh.
Right.
And since we are cheap whores.
I'm slowly getting used to that.
Yeah, you don't like that.
You don't like anything to do with money.
No, no, just money.
This was my idea.
I'm like, give us money.
We'll do whatever you want.
All right.
First question.
All right, first question.
What would be the most exciting find that you would have via X-ray telescope?
Like, what would be the piece de resistance, so to speak?
This is what he says.
Okay?
This is Deezus from Patreon. Okay. This is Deezus who from,
from Patreon.
Patreon.
Okay.
Deezus.
Well, I mean,
I think there's a lot of,
if you ask that question
of a number of different people,
there'd be a lot
of different answers.
I think like for me
in general with astronomy.
You're making the images
so you get.
I know, I know, I do.
You get top pick here.
I get top pick.
It's too exciting.
For me, just with my biology background,
I have to say anything to do with finding life,
possibility for life on other planets.
I mean, when I first started working for Chandra,
exoplanets weren't really a thing.
This was like late 90s, and they weren't really,
I think maybe there were one or two discoveries at that time.
There were a few, yeah.
The first was 1995.
Right, exactly.
They're all the rays now.
Yes, they are all the rays.
Now there's thousands of them, I think.
And Chandra has some really interesting capabilities
to study, especially the effects of the host star
and how that might have habitability issues
with its, you know, children planets.
So I think anything to do with exoplanets,
for me, that would be super exciting.
So this is extra information brought to us by X-rays about these objects we already know of.
Right.
How about objects that we would know nothing of were it not for their X-ray signature?
So, all right.
What would you put at the top of that list?
Oh, all right.
Well, I think—
Because really, your X-rays for exoplanets are supplementing other data.
They're helping the bigger puzzle.
The bigger puzzle.
Yes, yes, yes.
Give me one where the x-rays are the only pieces in the puzzle.
Well, so I'm too much like a multi-wavelength astronomy junkie here.
Oh, wow.
Look at that.
You're asking me to choose one of my children.
That's exactly how it feels.
This is the Sophie's choice.
And I would never pick one of my kids over the other.
And they're listening, so I know that for a fact.
So, anyways, but yeah, I feel like these days,
it's all about how the different kinds of light
are each one tool in the toolbox of astronomy, right?
Very good.
And it's truly about how all of those pieces fit together.
So, X-ray astronomy complements really well with radio astronomy, with optical.
I mean, it's really, it's hard to pick just one.
Okay.
So this is the healthiest way to think about that.
Yeah.
That you are a cog in a wheel.
Right.
A puzzle piece to a larger, organized understanding of the universe.
Right.
Yeah.
And with the addition of like gravitational wave science.
A whole new window.
That's yet more.
Yeah.
So multi-messenger
gets exciting.
I mean,
there's a lot to go there.
So I can't just pick one.
You can't pick one?
No, I can't do it.
There you go.
All right.
Can't just have one.
Nope.
There you have it.
I like the concept.
And are you showing off
your cell phone here?
Maybe.
Look at that.
It's beautiful.
That is gorgeous.
So that's a skin or a cover? It's a little case. It's a little case. gorgeous. So that's a skin or cover?
It's a little case.
It's a little case.
I mean, this is NGC 602.
It's a beautiful stellar evolution area.
Baby stars being born.
Stellar nursery.
Stellar nursery.
Lots of babies in there.
And you've got this.
The purple is the X-ray data from Chandra.
And then there's also some infrared data from Spitzer.
Chuck, are you making crying babies?
That's my baby star. That's my baby star.
That's my baby star.
And I just randomly found this on Amazon one day, which was, I think, so cool.
And I was like, I know that image.
Because?
Because I think so, too, because I worked on it.
You created that image?
Well, with a team.
I mean, nobody, one person does anything.
Sure, of course.
Right.
You scientists are always so damn humble.
You know what I mean?
You can't be, otherwise we'll smack you down.
Because you could be wrong next week.
Right, right.
And you're in a doghouse.
Exactly.
And you guys kind of all need each other.
Nature is always more clever than any of us.
Right.
Oh, there you have it.
For sure.
Oh, I like that.
Nature is always more clever than any of us.
Oh, yeah.
Completely agree.
Yeah.
And sometimes it's more clever than all of us combined.
Wow.
So one thing, so just to emphasize,
your X-ray data
is part of other data
that's combined
to make that image.
So multi-wavelength astronomy,
again, at its best.
This is kind of
a great observatory classic
with Chandra Hubble and Spitzer,
which I think is really beautiful
and it just helps tell the story.
You know, X-rays, I think,
are thought of...
So Chandra's X-rays,
Hubble is obviously
visible light,
and Spitzer's infrared.
So two very different branches of the spectrum.
Oh, very much.
But combined to make one image as though our eyes could see that broadly.
Right.
So if you had sensors in x-rays, visible, and infrared.
You'd be able to put this all together.
And you'd look up and you'd see that.
You'd see that.
Right. So if you were
Predator, you could actually enjoy
that. Or Geordi. Or Geordi
LaForge on Star Trek. Correct.
That's cool. Yeah. You could tune
that sucker up. Yeah. You know, Geordi had
the opportunity not to be blind and he
turned it down. Really? Yeah, in an
episode of Star Trek, you know. I missed that one. And I think
it's because he actually saw your image.
That's probably a nice... Well, the know? I missed that one. And I think it's because he actually saw your image. That's probably a nice...
Well, the thing is,
we are practically blind
when you consider how narrow
is the slice of the electromagnetic spectrum
our retina shows us.
We are practically blind.
Wow.
Yep, we can see so little,
just like a tiny sliver.
You know, you open a book
and it has the rainbow,
you know, the colors of the rainbow,
red, orange, yellow,
Reggie Biv. Right, red, orange, yellow,
rudge-y biv, red, orange, yellow, green, blue, indigo, violet, don't forget indigo.
Right?
And so it fills the page, but you look at the entire range.
Right.
And I'll recite that now.
It goes from high energy to low energy. You go from gamma rays, x-rays, ultraviolet, violet, indigo, blue, green.
Green, red. No, no, green, orange, yellow, red. Right. Violet, indigo, blue, green. Green, red.
No, no, green, orange, yellow, red.
Okay.
Okay?
Then you come out of the red,
you get infrared.
Infrared.
And then you get microwaves,
and then you get radio waves.
Wow.
When you put all that on one page,
visible light is this tiny little sliver.
So if you have like a piano in front of you,
it'd be like human vision is middle C
and maybe a couple keys around it.
That's it.
Barely an octave.
All the rest of the keys.
Not quite an octave
around middle C.
So, are there any...
So, imagine listening
to Beethoven's
Ninth Symphony
with just three keys.
Very boring.
Yeah, that's terrible.
Yeah, so we're basically
buying.
So, he did the right thing.
I hate my eyes now.
I know.
No, no, no.
God, I hate my eyes.
So, let me ask you this then.
Are there any animals that see outside of the spectrum?
Deer.
Deer?
Deer can see a little bit ultraviolet.
A little ultraviolet.
Insects are told all about ultraviolet.
Bumblebees.
Yeah.
Bumblebees see ultraviolet as well.
Yep, a little bit.
And you know that they like ultraviolet?
Okay.
This is how we know we are smarter than insects.
Okay. Okay? Evidence we are smarter than insects okay okay
evidence we are smarter than insects all right okay cool no one is stepping on us to kill us
we we invented bug zappers which are intense and ultra violent and they so i can't stop it right
exactly exactly and that's how we know we are smarter than they are.
And bug bulbs, which you don't see much anymore,
they're kind of amber.
Right.
They don't repel bugs.
Bugs don't see it.
So their entire sensitivity to light
is shifted towards the blue end into the ultraviolet,
and it dangles off the other end some red and orange.
So it's not that
they avoid the red bulb
over your picnic table.
They don't see it at all.
They can't see it at all.
Yeah, and if you put
a bug zapper
at the end of the lawn,
they all go to the bug zapper.
So I just want you
to appreciate
that we are smarter
than bugs.
So if the alien invasion
comes and it's bugs,
we should just rely
on our zappers.
Oh, good.
Is that what you're thinking?
If they are bugs.
Yeah, but you know what? If they are bugs, that's
what I'm thinking.
If they were smart enough to get here
and we're too stupid to leave here,
something tells me they're going to have the
equivalent of a bug zapper for us.
Like a concert.
Just like, oh my god, free concert.
Free concert and good food.
Free concert and hamburgers, what?
We walk in and zap. And no one comes out to tell and hamburgers. What? You know, we walk in and zap.
Zap.
And no one comes out
to tell you not to go.
Exactly.
Because everybody got zapped
when they were there.
Dude, that must be
the best concert ever.
It's been going on for six days
and nobody's come out.
Yeah.
That wouldn't be fun.
Yeah, we would be putty
in the hands of a smarter species
for sure.
All right, next question.
Here we go.
Pentybot on Instagram
wants to know this.
Since you guys were talking
about the different types of light in the spectrum,
what is the difference between Chandra X-ray Observatory and James Webb Telescope?
Is it just the spectrum of light or what else do they do that is different?
Let's start out with the orbit.
So what orbit is Chandra in?
So Chandra's in a highly elliptical orbit that goes about a third of the way to the moon.
Chandra's about the size of a school bus.
It weighs maybe 4,800 kilograms, something like that.
On Earth?
Yes, exactly.
Exactly.
Very important detail.
On the moon, it weighs one-sixth of that.
You know, actually, the interesting thing about Chandra is it was, I'm pretty sure,
still was the heaviest thing that the space shuttle ever launched.
Really?
Wow.
And the fact that it was so massive meant that, and I didn't actually learn this until many years later,
the fact that it was so massive
meant that it was a more riskier ride
for the astronauts than it would have been
with a lighter payload.
Their abort scenarios, for example, were
more challenging, but I
didn't know that at the time. So, yeah, so
Chandra was large and in charge, and it was
fortunately perfect.
Large and in charge. Everything went perfect to get it up into space, thanks to the astronauts.
And so that's that orbit.
And so James Webb is a million miles on the other side of the moon.
Right.
So they want that away from Earth interference.
Right.
So James Webb is an infrared-based telescope.
And again, different parts of the spectrum would tune differently.
based telescope.
And again, different parts of the spectrum would tune differently.
And so they have their targets
of interest. Their objects of affection
in the universe are different.
But then you bring them all together and you get
the full picture.
So now, you mentioned the orbits.
This is a question coming from Chuck Nice on Facebook.
Chuck Nice here in the office.
Let me just comment about
I have to say something
a little more
about James Webb
go ahead
so
so Chandra's in this
big elliptical orbit
so it's orbiting Earth
yep
James Webb is
in a Lagrangian point
ah
it is a point
where all
forces that would
otherwise move it
are stable
right
and so you put it out there
and it takes very little
station keeping
to just keep it there.
And this is the
famous Lagrangian points
are where we imagined you'd build
stuff. Right. Because you just get all your hardware
and just load it there. Right. You leave it there.
It'll just hang around. It'll just hang.
It's the garbage patch of the solar system.
It'll collect it.
I need a bolt or a screw. There it is.
It just hangs right there.
It doesn't fall to anybody's surface.
So imagine to be a little more useful than they've turned out to be.
It turns out we can make things that are orbiting.
It's not that hard.
Because once you bring something up into orbit, it orbits with it.
With you.
Yeah, yeah.
So it's not.
Although I do love the Lagrangian point as a place.
It's a cool name.
It's a total cool name.
Right?
Exactly.
Lagrange.
Lagrange.
Lagrange.
All right, so now let me ask you this.
Okay.
As these orbits happen, are they staying on a fixed point,
or are they observing different quadrants as they move around?
So Chandra goes a third of the way to the moon at its farthest point
and then goes about 16,000 kilometers to Earth at its closest point.
So it's this nice elliptical orbit.
And they did that for optimal observing capabilities
so that it has the most time to essentially be looking out at the universe.
Gotcha.
Far away from Earth.
Far away from Earth, exactly.
But yeah, I think what's really interesting about, well, for one thing, gotcha but you know far away from earth far away from earth exactly but yeah
I think what's really
interesting about
well for one thing
I think it must have
gone like 2.7 billion miles
I mean kilometers by now
over 20 years
which is I think fantastic
and you think about it
like Tinder's never had
a day off
in like 20 years
doesn't even have
like an hour off
she works hard for them
right
I know
and how perfect
that had to work
when it was launched
so anyways
but I'm not sure
what James Webb is doing.
Right, so, well, it's not up yet.
Well, true.
At the time of this broadcast.
Yes.
But so these things have gyros that enable you to know where you are and where you're pointing.
And so you send coordinates up there, and you pick out your object of interest and gather data.
So there are some, I think I understand the point of that question.
There are some telescopes
that only observe
one patch of sky.
And they hammer that
for,
they get better,
deeper data.
Kepler did that.
Right.
Kepler was one patch
of sky looking,
there was a lot of stars,
but it was still one patch
looking for exoplanets.
And,
because it had to go back
looking for variations
in the host star.
Right.
So one set of data is not good enough. You've got to go
back and back and back. Compare all the
different images. Compare all the data.
So, and let me take this
moment. Let's go over just who these people are.
Okay? So James Webb
was the, he was head of NASA
during the 1960s. Cool. Yeah.
And, but he was, I think
he was the first person
who we named a telescope after that was not a scientist.
So I think there might have been some political stuff going on in the back room.
That's kind of cool, though.
I think it was the first naming before launch, too, right?
Oh, yeah, yeah.
Normally you name it after a person after launch.
Yeah.
Just in case it blows up or something.
Bad luck.
Your name blows up with the thing.
Chandra was AXaf for a long time.
I forgot all about that.
And Aksaf doesn't quite roll off the tongue.
X-ray astrophysics facility or something.
Advanced X-ray astrophysics facility.
Yeah, yeah, yeah.
But then it was renamed Chandra after Subrahmanyan Chandra Sekhar,
who is a very famous Indian-American Nobel laureate
who studied things like white dwarfs and stuff like that.
Very nice.
And he also did say, I probably have a book about Chandra.
Let me see here.
Hold on.
There it is.
Subra Hamanyan,
Chandra Sekhar.
Yep.
Radiative Transfer.
So one of the more
brilliant among us who...
Okay.
I'm through.
I can't even with you.
What, what?
I'm just done with you.
What, what?
Like seriously.
What, you got issues?
Yeah, I got issues.
Because I'm not an asshole.
This is the crap.
The crap, not crap.
It is?
But this is what you're reading? Yes. You're sitting around reading this? Yeah. Give me this for a second. No. Give I'm not an asshole. This is the crap. The crap, not crap. It is? But this is what you're reading?
Yes.
You're sitting around reading this?
Yes.
Give me this for a second.
No.
Give me that for a second.
What?
I can't believe that.
Okay, people at home.
Open any page.
I'm just going to wait.
Let me just open up.
Okay, here's the page.
Oh, you're going to read this to Ben?
I'm going to read it.
It's not light reading.
I'm going to read to you.
Red Top Stories from Radio Transfer.
Exactly.
Principles of Invariance. What is that? What is that? Squiggly Transfer. Exactly. Principles of invariance.
What is that?
Squiggly line.
What is that?
Squiggly line.
Squiggly line doodle thing.
And by the way, this just goes on for page after page after page of this.
Some of the pages are just nothing but actual equations.
I have seen Chinese newspapers that are easier to understand than this.
All right.
So, Chuck, if you write a book like this, you get a telescope named after you.
That is true.
Unbelievable.
So he's wrote several books that really were the definitive word on those subjects.
And they're still used in graduate school.
Yeah, and it was a naming contest.
We actually had a contest for the naming.
And it was a teacher and a high school student
that picked the name Chandra as the winning entry.
Oh, very cool.
They knew.
They did some excellent research and did not mind the equations.
So we've got to take a break.
We have more questions coming up on the X-Ray Universe
with Kim Arcand.
I say that right.
It's French, but I'm Americanizing it.
You tried to French it as good.
I tried to French
our con
Kimberly our con
Chuck nice
we'll be back
in a few moments
the future of space
and the secrets
of our planet revealed.
This is StarTalk.
We're back.
StarTalk Cosmic Queries.
The X-ray edition.
And I've got the leading visualization person for the Chandra X-ray telescope, Kim Arkhan.
Kim, welcome to StarTalk.
You're a first-timer.
Thanks. I hope we get you back.
Yeah.
And Chuck.
Hey.
Always there.
You're there for me.
I am always here for you, my friend.
I love you, man.
I love you, too.
Okay.
So what do you have?
Let's go to...
These people.
What's that, Chuck?
God.
You just made this name up.
What?
All right, go.
Adamaroidia.
Adamaroidia.
I'm going to go with that.
On Instagram,
I want to know,
how many more stars can we detect
with a Chandra X-ray observatory
than we can see with our naked eye?
And can we detect exoplanet transits?
Can I reshape that question?
Yeah.
I look up at the night sky.
The human eye can see about,
in the total sky that is below and above you,
about 6,000 stars.
A few nebulae, you know, with the naked eye.
So how boldly different,
if you could just turn on X-ray vision
in a Chandra sense,
what do you begin to then notice?
What begins to pop?
I think it's more than just the stars.
So I guess it's quality over quantity, right?
It's not just the numerical number that we guess it's quality over quantity, right? It's not just the numerical
number that we're going to be looking at, but more of like telling about what they are.
So for example, if you looked at a patch of the sky of Orion Nebula, for example, and
you looked at that in optical light.
Which is the closest stellar nursery to the sun.
All right.
In the constellation, among the stars in the constellation of Orion.
You can look at that in optical light and you'll definitely see a lot of stars.
But as soon as you look at an X-ray light, you're going to see the same tiny small patch.
You might see like, I don't know, 1,700 X-ray sources.
But those aren't going to just be plain old stars.
I mean, you know, not that stars are just plain and old, but you know what I mean.
You might see binaries.
You might see black holes.
You might see other types of these celestial objects.
So I guess for me, it's
just, yeah, it's not the quantity so much as the quality of what you're studying. And then you're
also going to see diffuse emission, kind of like some of that hot bath that those stars might be
sitting in. So hot gases will radiate x-rays, and you're not going to see that with your naked eye,
and you're not going to see it with your regular telescope either. Right. So the whole new world opens up.
Right.
Another example would be something like Cassiopeia A, the supernova remnant.
Chuck, you're nodding like you knew all about Cassiopeia.
Listen.
It's a good one.
What can I say?
It's a famous one.
What can I say?
Even though it's not like it was a, you know,
it's not like it's something that is very esoteric, you know what I mean?
To be honest.
A supernova exploded.
I forgot the year that that happened, but there's a remnant of this exploded star.
And we kind of knew it was there, but now Chandra gives us a whole other view of it.
A whole other world.
It's really amazing to look at.
I mean, you can look at it with optical light from like the Hubble Space Telescope,
and you'll see this beautiful filamentary structure.
I'm a very visual person, obviously, so I'm like lacking my images,
but you'd see this
nice, delicate
filamentary material
around the 10,000 degree mark,
right?
Kind of looks like
a hollow shell.
But yeah,
so you can look at Cass A
with the Tandrix Observatory
and it looks
completely different.
It's like literally
death come alive.
It's a solid looking
sort of thing.
Death come alive.
Yeah, well, it's death,
but it does lead
to future generations
of stuff.
It's animated death. Yeah, it is. It is moving. it does lead to future generations of stuff. It's animated death.
Yeah, it is kind of way.
It is moving.
It's evolving.
Go on.
Feeling poetic.
Feeling very poetic.
Man, I can't.
I got nothing.
I got nothing.
But it's amazing because you can trace
where the iron is dispersed
and where the argon and the silicon is,
and it just makes this incredibly gorgeous nebula to look at.
New stars arrive from the ashes of that which has burned.
Nice.
That's exactly it.
Now can I hang with y'all?
Yes, that's very nice.
That's poetic.
That was very cool.
So is Cassie, I always forget,
is that the brightest source of X-rays in the sky?
No, Skull X-1 is.
Oh, Scorpios.
Yeah, exactly.
Scorpios X-1, okay.
Yeah, but Cassie is really bright,
and it's great for Chandra.
See, now, you had to do it, didn't you?
What?
You had to go, you know, I was cool with Cassie, okay?
And then you had to go to Sko.
Sko.
And what is Scorpio?
Scorpius, the constellation.
The constellation, yes.
Okay.
Now, I'm old enough, okay?
I'm old and all y'all, okay?
I worked at the Center for Astrophysics, which is a big X-ray place
up in Cambridge, Massachusetts,
as an undergraduate.
Nice.
And for my summer project,
I worked on one of the earliest
X-ray telescopes that were launched.
So there was Uhuru,
which was an X-ray telescope.
Right.
And the receptionist on Star Trek.
Oh, Uhuru.
Uhuru.
That's her brother, Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru.
Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. Uhuru. her brother. Uhuru. Uhura.
But she was not the receptionist, dude.
She was a lieutenant, first of all.
Yeah, this is true.
And a communications officer.
So the first telescopes that go up,
they just kind of look for anything that gave up X-rays.
Right.
And then they created a catalog.
Sweet.
And they numbered the X-ray sources within each constellation.
So by order of brightness.
And so in Scorpius, the brightest one was X-1.
So Sko X-1 is.
And there's also a Cygnus X-1.
That's a good black hole candidate.
And so when you see the X and the 1, we got our first X-ray telescope.
Cass A was named before we had X-rays.
And so now the detection of those, so, you know.
Oh, by the way, those early telescopes, it was just to know that they're even there at all.
That's what I was going to say.
Yeah, yeah.
So now you've got Chandra.
Chandra is.
That's what I love about X-ray astronomy is, like, I mean, there are a lot of people on this planet whose whole lives have been the length of X-ray astronomy.
Like, the field is so young.
I think, I mean, it really got going late 40s, early 50s.
And then by the time I was...
Well, for when they had detectors, yeah.
Exactly.
And by the time I was born, there was a good one detector on Skylab.
And then by the time, like, by the time my kids were born, like, you know,
Chandra had launched and XMM Newton was launched.
And now they're working on new generations of X-ray telescopes.
So Chandra was 92 or 99?
99.
99.
2019 is its 20th anniversary.
That's 20, okay.
Yeah, the summer.
Now, before that, you're looking at images
like 100 times kind of dimmer or fainter, right?
Much fainter.
I mean, it started out like looking at the sun
to just get X-rays from the sun first
because it's a nice nearby target.
Is the sun bright enough, you think?
Exactly.
Chandra can't look at the sun
because it's so bright.
Because it's too bright.
Okay, yeah.
It would like fry Chandra off.
I can look at the sun.
Never mind.
Oh, right.
No one should be looking at the sun.
How's that?
Especially not Chandra.
But yes,
and then, yeah,
with like Uhuru and Einstein,
like all these other missions,
it's just been an amazing,
like compact amount
of x-ray astronomy that's happened
in just a handful of decades.
But it took a normal course of evolution.
It did.
So you first got to know,
you want to learn that there's any kind of source of X-rays at all.
Something to detect, exactly.
Here, there, there.
Right.
They're blunt instruments, right?
Then you kind of wonder what it is.
You might do some calculations, but still you don't know.
And the later generations, you say, now that I know they're there
and I know what kind of signal it's giving me,
let me devise a detector that
can more precisely measure that.
Or measure something dimmer.
And so, like you were saying, you see
the dimmer ones, you get more precision in your
image, you start making X-ray
images. Right. And now Chandra's images
are so sharp and beautiful. I mean, when you're
looking at things like supernova remnants and it's just
so much detail that you're seeing,
never mind what the next generation of X-ray telescopes
will be able to do, like 100 times more sensitive.
Will the next generation say,
you know, back in 2019,
Kim thought she had
high-resolution images. I'm sure. I hope
they do. But she was,
she had nothing. She had nothing. Yes,
that would be perfect. That would be great.
That would be the best thing.
The best thing if you were obsolete-ified.
Yes.
Does everybody want that?
Yeah.
Yeah.
Cool.
All right.
Should we go to another question?
Yes, let's do it.
Let's do this.
This is Chris Cherry from Instagram says,
What is the next light spectrum we'll be observing in the universe?
Or observing the universe in?
All of them, all the above.
I mean, I guess it depends on what they mean by that question.
If they mean what's next to be launched,
I mean, hopefully the James Webb will be the next to be launched,
and that'll be infrared.
And then beyond that, it's whatever's in the budget
and what other agencies are able to do.
Whatever's in the budget. Right? agencies are able to do. Whatever's in the budget.
Right?
That's funny.
I love that answer.
Great answer.
It's true.
Yeah.
What's the next spectrum?
Whatever's in the budget.
That's the next spectrum.
But ideally
all the light.
We want all the light.
Right.
Very cool.
But here's an interesting challenge.
Okay, so let's
so radio waves
have very long wavelength.
Right.
And one bit of evidence of that is those who remember televisions that had rabbit ears,
they're detecting radio waves as television signals,
and the length of the rabbit ear is commensurate with the length of the radio wave that it's trying to capture.
So that's, okay.
So suppose you want to detect a radio wave that it's trying to capture. So that's... Okay. So, suppose you want to detect a radio wave
that's a meter long or 10 meters long or a kilometer long.
How are you going to detect that?
You need a detector that is at least that size.
Right.
So you can get a whole wavelength in there
or at least half a wavelength.
You need some fraction of that wavelength
hitting and being able to focus it.
Suppose there's something out there that makes
a radio wave that
is the diameter of Earth's orbit around the
sun. Who's detecting
that? So, there could
be phenomena in the universe
that is washing across
the entire solar system, and we
don't have detectors that can pick it up.
Wow.
I do like radio waves.
If I had to pick a second favorite besides x-rays,
I think it would be radio waves.
That's a nice pair of waves right there.
Yeah, they really are.
They're very complementary.
Yeah.
It's true, even though they're on opposite parts.
They're opposite parts, but they're good.
But opposites attract.
I mean, it really does.
Plus, they're highly used in our culture.
Radio waves for communication and x-rays for medicine.
X-rays for health.
Yeah.
Very, very cool.
All right.
Could there be a, oh, sorry, Julie H., who comes to us at Time Traveling on Twitter.
I like that.
She says, could there be technology like Street View on Google Maps that visits various points, just points in the universe?
Oh, that's a great question.
Interesting question, right?
So we have Google Mars, I think it's called.
You can look that up, googlemars.com,
or maybe it's mars.google.com, whatever.
That it's almost like street view
of some of the data on Mars.
And that's really amazing.
Getting more three-dimensional,
which I think is the point she's kind of getting at there,
data of our universe is really
hard. Once you're going beyond
nearby objects in the solar system
and you're going farther out past the stars,
it's really hard to get some sort of
usable dimensional data on that to then turn
into like a 3D model that you can
tour in like a street view type of map.
So you think you don't do 3D
modeling for Chandra?
We do.
You do?
It's just hard.
Oh, okay.
But we do, yeah.
Actually, I do have a 3D model here.
Not because they're easy.
But because they're hard.
You brought to show and tell.
I did bring something for show and tell.
Because again, I'm a very visual person,
which does not help the audio folks.
I know.
But we can describe it.
Yeah, so it is a kind of globular looking structure and it has many different nodes that are jutting
out from it.
It looks like a tumor removed from somebody's body.
It really does.
But there's a reason for that.
You know, it looks like calcified coral.
That's what that looks like. Oh, very good. Yes, it does. Is that good? Wow, Neil. So why it looks like calcified coral. That's what that looks like.
Oh, very good.
Yes, it does.
Is that good?
Wow, Neil.
So why it looks biological, though, it's because we actually used brain imaging software adapted from some local area brain scientists in the Boston area to make it.
We used their software.
So that's why it looks more brainy-ish or biological-ish
than you would probably expect otherwise.
That's funny because before we sat down,
I picked this up and I said,
is this like a firing neuron?
Right, right, right.
So there's a lot, yes, yes.
Well, I mean, if you look at visuals
from the micro versus macro,
now you're speaking my language
because of my biology background,
but you can see so many similarities
in the way that you process those data, right? But what you're holding is a 3D model of Cassiopeia A,
our good friend that we were talking about earlier, the supernova remnant. That's so cool.
Yeah. 10, 11,000 light years away. And you're able to hold a version in your hand,
essentially because of the Doppler effect. So did you 3D print that?
Yeah, this is 3D printed. Okay. Yep. Yep. So we worked with-
So the Doppler effect gives you depth information.
Right, exactly.
So Tracy Delaney, she was a scientist who first worked on this.
She was at MIT at the time, and she was essentially figuring out what information was moving away
and what was moving towards this using the Doppler effect.
Was she with their imaging lab?
MIT has a big and famous imaging lab.
No, she wasn't actually.
This is separate, but we hooked her up with the folks who were working on the medical
imaging software translation, which was called Astronomical Medicine.
That's cool.
I like that.
This was the result.
I like that hybridization.
Yeah, yeah.
This is fascinating.
I love it.
So scale is an issue, though.
Obviously, when you're holding something that's small, this is like four inches across for those listening, maybe.
What we can do, maybe we'll photograph it.
We'll post it next to the audio.
In real life, it's like the surface area is maybe 40 million billion times the surface area of our sun and planets.
And you can toss in Pluto if you like.
It doesn't matter.
Yeah, yeah, Pluto.
Or toss it out.
But yeah.
I buried my hatchet with Pluto.
Oh, good, good, good.
Pluto, we're good.
Good.
All right, Chuck.
Only you have to bury the hatchet with a Pluto.
With a dwarf planet.
I was about to say planet. With a hound dog. Exactly. Bloodhound. Yeah, Chuck. Only you have to bury the hatchet with a dwarf planet. I was about to say planet.
With a hound dog.
Exactly.
Bloodhound.
Yeah, yeah.
All right, do we have time?
Let me hear the question.
All right, I'm going to give you the question.
This is Tom Ricks from Facebook.
He says, do you think virtual reality will ever allow the human brain to completely comprehend the immense distances between planets, stars, and galaxies,
or is this something that we'll never fully grasp?
We will answer that after this break.
Nice.
See what I did there?
There you go.
It's called a tease.
It's called a tease.
This is StarTalk, Cosmic Queries,
X-ray Astrophysics Edition.
We'll see you in a moment.
The future of space and the secrets of our planet revealed.
This is StarTalk.
StarTalk Cosmic Queries.
X-ray astrophysics edition.
We're celebrating the 20th anniversary of the launch of the Chandra X-ray telescope.
One of the great observatories.
Up there with Hubble and James Webb and the rest of them.
Each of them targeting their window to the universe.
Nice.
Kim Arcand.
Hello. Yes.
And Chuck. Yes.
So we left off. We left people
dangling. Yes. Where can virtual
reality help us comprehend
the scale of sizes and distances and things?
Let's make this a more broad visualization question.
Part of your job, Kim, is to get people to see things we don't otherwise see
or to grasp scale and texture and phenomenon
that is not otherwise accessible to us looking on our Instagram account. Right. So what role do you see that you play in getting us closer to the universe?
Oh, that's a great question.
I think mostly my job is to just sort of oversee all the various visual platforms
that we can take Chandra data to.
I mean, we...
Oh, so not just photographs.
Not just images, yeah. I mean, Chandra Oh, so not just photographs. Not just images, yeah.
I mean, Chandra, one of the great things
when you have a telescope that's been up there for so long
is you just have a fantastic archive of data to work with.
And as technology has developed in other sectors,
you have all of these new platforms to try it out with.
So we were talking about 3D printing earlier
and the idea of what you do with 3D models.
So you've got to stay current with all that.
You do.
You've got to exploit it in your service.
Yeah, when I started working for Chandra,
Cassie PA was one of the first objects we ever looked at, right?
And it was beautiful in a flat two-dimensional image,
and I was amazed.
Never would I have imagined, fast forward 20 years,
and I'm holding a version of it in my hand
or walking inside it in virtual reality.
Those technologies were not a reality at the time.
So with things like virtual reality or augmented reality, mixed reality, data sonification using sound, there are all of these ways to take that.
Data sonification.
Yes.
So add another sense to the interpretation of the data.
For example.
Is this also good for blind people?
Exactly.
Dr. Wanda Diaz actually has done a lot of work around that.
Exactly. Dr. Wanda Diaz actually has done a lot of work around that.
My kind of perfect world would be a virtual reality application where you have the visual, of course, but then you have the layer of sound
that's also spatially attached, so you know where things are.
And then also like a haptic layer, so you can actually feel vibrations.
I don't know what that means. Haptic. Touch.
So like, you know, when your phone vibrates.
Why don't you just say touch?
Because haptic is a much cooler word.
Touch layer. I know. It's called haptic technology.
That's what we use.
I don't know.
But yeah, it's essentially by being able to feel those vibrations as you're moving through
the remnant, right?
So there are all these applications, none of which were around.
So we'll be through the remnant.
So we have the 3D model and you become a journey.
You journey through the model.
Exactly.
Exploring it.
Now, the scale is still hard.
Oh my God.
They used to have that at the Franklin Institute. It was a heart. Oh yeah. Yeah. I remember. The living Exactly. Exploring it. Now, scale is still hard. Oh my God, they used to have that at the Franklin Institute.
It was a heart.
Oh yeah.
The living heart.
The living heart.
You would walk through the heart.
So think of that except virtual, right?
But then having cues of sound and touch
and it's a wholly different understanding
and experience of that information.
Now, going back to the question of scale,
I mean, as soon as you get out of Earth-sized scale
and even smaller than that,
it's really hard for human understanding
and relations of what we know.
So whether that will actually help people understand
and comprehend some of these vast scales,
I don't know, but it helps.
It might help, but here's the thing.
It's just not...
Everything that we see,
we imagine on the scale that we see it yeah because that's the
scale in which we live exactly and so scale in which our senses were forged correct yes so the
problem is that even if you were able to demonstrate it your brain would be resistant to actually then
revisualizing it that way because you're so used to looking at you know the world through the eyes
that you have which is like neil does this thing where he shows um which i first time i saw it
because he did it for me what i was like get out of here and he showed me just where the moon
and the sun and the earth are right and it was like relative to each other and we just did it
with like a basketball
and something else.
And we did it
in a regular room
and I'm like,
you got to be kidding me.
Right.
Like, you know what I mean?
So even being able
to see it in the,
you know.
And those are just planets.
And those are right.
Those are just planets.
That's your backyard, dude.
We're talking right here.
We're not talking about
gouges.
That's crazy.
So yeah,
I don't think the human brain
could ever comprehend
those vast scales. It's just too much. Cool. Yeah. Oh's crazy. So, yeah, I don't think the human brain could ever comprehend those vast scales.
It's just too much.
Cool.
Yeah.
Oh, man.
This is good stuff.
I got another quick one just while we're there.
Yeah.
You might ask, you see all these stars in these photos, and you say, will stars ever collide?
Well, they do rarely, but they do and they can.
And it's interesting when that happens.
they can, and it's interesting when that happens.
But to appreciate how rare that is, if there
were four bumblebees
in the United States flying
randomly, there's a higher
chance that two of them will accidentally bump
into one another than for
two stars to collide in the galaxy.
That's a great analogy.
Four bumblebees.
So you look at their size and the distance between
them. That's kind of what you're getting. the size of a star relative to the distances between them.
Right.
That's a good one.
And by the way, if there's only four bumblebees, we're all dead because there's no food.
There's no food.
Nothing gets pollinated.
Nothing.
I hadn't thought about that.
Now I feel guilty, dude.
All right, next question.
All right.
Before we go to lightning round.
Here we go.
Jonathan Gallant wants to know this.
Hey, it's Jonathan from Edmonton.
How far away from...
You know what?
We did this already,
but I'm going to give it to you anyway.
He's taking it one step further
than the last question.
It's a follow-up, we'll call it.
How far away are we from a Star Trek-like
stellar cartography room
like they have on the holodeck?
In the next generation.
In the next generation, yeah.
Next generation, the holodeck. I really next generation. In the next generation, yeah. Next generation, the
holodeck. I really like that question.
It's a great question. We're actually just
starting to experiment with holograms. Oh.
But screen-based holograms.
So not, you know, just sort of appearing in the room.
Not Help Me Obi-Wan Kenobi, You're My Only Hope.
That was really geeky. I mean. Oh my gosh.
But that was good. Oh my gosh.
Oh my gosh. I didn't know you had it
in you. It's there.
I mean, and I think with like missions like Gaia and others, you know, building this sort of nice 3D map.
I mean, our world is 3D.
So being able to bring some of that 3D nature into a way that we can visualize, understand it, and then explore it.
I think it's really important.
I really do.
And it's awfully fun.
Very cool.
Yeah.
Excellent. Excellent. I don't even really important. I really do. And it's awfully fun. Very cool. Yeah. Excellent.
Excellent.
I don't even know
if we have enough questions left
for Lightning Round.
We can just chill.
Chill with them.
All right, let's chill with it.
This is...
Let me slip in a question here.
Go ahead.
So,
can we just go back to basics?
Yeah.
When you're going to make
a simple color image
of something that has no color,
and you're using your x-rays to do so,
what are your steps?
Well, so first we get the data from whatever object it is.
If we want to use Cass A as our example.
That's the favorite object of the day.
It's just the favorite object.
It's actually one of my favorites, if I want to admit it.
But we first get the data in.
When it first comes down, it's actually transmitted and coded favorites if I want to admit it. But we first get the data in, you know, it's, when it first comes down, it's actually transmitted and
coded in the form of ones and zeros.
Then it goes through some software and then it's
translated into a table that shows the X and Y
position of the observation,
the time and the energy of each of
those packets of light that struck the
detector during the observation.
Oh, by the way, we could
measure visible light in the form of energy, by the way, we could measure visible light
in the form of energy, we just don't.
The way we do it is we measure it
by color. Right.
So, oh, this is a blue photon, and this is a
red photon, and we just say it's blue
and a red. But if we did
a Chandra thing on this, we'd say
this is the higher energy photon, this is a lower
energy photon, and the blue would have higher energy
than the red. Right. So, it's really the same thing,, this is a lower energy photon. And the blue would have higher energy than the red. Right.
So it's really the same thing,
but they have a whole other,
the detectors measure this in energy.
So the vocabulary and the steps are shaped for that.
Right, exactly. Okay, so sorry to interrupt.
Yeah, no, no.
Slap that in there.
Okay, go.
More software,
and we finally get the visual representation of the object.
And I like to use that word,
that term for a reason,
because I think there is this idea
that these images of the universe are giant cosmic selfies, you know what
I mean? Snap done and they're not. They really do take people like me or like whoever to do the
creation step because it is light that you can't see. So then you create the visual representation
of the object and then you refine it. You have to get rid of artifacts or bad bits of data.
You have to smooth it. You might have to
crop in the field of view that you need
and then usually the last step is color.
And I like to
slice and dice an image by energy level
essentially. So the lowest energy
x-rays will be assigned red, the medium green
and the highest blue. Unless we're adding it
to optical image from Hubble or
Spitzer infrared image. That means you can't
take their color. Exactly.
You have to share.
You have to share the color.
Sharing is very important.
We only have ROYGBIV.
You gotta, you know,
spread the love.
Sharing is caring.
Exactly, sharing is caring.
And then you compile it together
and you get your color image.
All stuff you couldn't see.
Even if it's optical range,
most of the stuff
is you can't see
because human eyes
are so puny.
Feeble, yeah.
Wow.
Yeah.
That is incredible. Yeah. That is incredible.
Yeah.
That's incredible.
So you're actually layering this stuff
one on top of another to form the image itself.
Right.
That's pretty cool.
But your retina is doing that.
So the cones of your retina,
they're red sensitive cells,
they're green sensitive cells,
and they're blue, RGB.
Right.
And light comes in,
it triggers one cell or another
depending on how much energy it has.
But we say it's depending
on what color it is, right?
I mean, it's an energy thing.
It's all about energy.
And so you trigger a certain amount
of the red, green, and blue.
And if it's more red than blue
or more blue than red,
it shapes what color it turns out to be
that your brain interprets.
So it's the same thing as your eyes.
Wow.
Or your computer screen or whatever.
Yeah.
Wow.
Have you ever looked
at RGB instructions
in the computer code?
It's just a level
of how much of one.
I'm going to be honest.
I have not.
You know what I go with?
Default.
Okay.
You don't go in
and program it.
Okay.
So the point is
if the colors are,
you can make arbitrarily any color once you have the RGB.
Right.
Just a mixture of those three.
And that's why.
And it only works there with light.
Don't try that at home with paint.
Right.
You mix RGB paint, you get mud.
You get mud.
Right, right.
Yeah, exactly.
Yeah.
Now, I did know that.
And my boy figured that out.
Who?
Isaac Newton.
Oh, really?
Yeah, he knew that people kind of maybe figured that white light can make a spectrum.
Right.
But he took the spectrum, put it back through a prism, and it made white light.
Right.
And that freaked people out.
Yeah.
How do you get red, orange, yellow, green, blue, violet, and get white?
White.
Right.
Yeah.
Well, thank you, Isaac Newton.
If it weren't for him, I would not have had a livelihood.
Not a livelihood. I wouldn't have been sustained growing up. Because my father was a printer. him, I would not have had a livelihood. Not a livelihood.
I wouldn't have been sustained growing up because my father was a printer.
Oh, I didn't know that.
And that's what printers do.
Yes.
They actually take light and they mix it to create color.
CMYK.
That's exactly right.
That's exactly right.
And that's from that exact same principle that you just said.
There you go.
Yeah, that's excellent, man.
Very cool.
Look at that.
See how science is a part of your life
and you don't even know it?
Here I am eating because of Isaac Newton.
It's a scratch, but it's okay.
But that is kind of the whole point of the show, Chuck.
Okay?
You're acting like that's some new revelation
about what we're doing here.
Okay.
Chuck, we got two minutes.
Let's see what we have.
All right, here.
Skynet is aware from Instagram says this.
So Chandra was originally launched in 1999.
How has the technology advanced since it was launched?
Do we have better technology 20 years later
that is more sensitive?
So...
Oh, okay.
Can I ask that differently?
Okay.
Okay, you ready?
Yeah.
Okay.
At what point do you say,
we've got such better
technology, let's drop Chandra in the Pacific Ocean and put up the better technology because
you're spending money on something that was conceived and designed not 20 years ago, but 25
years ago when it was still on the drawing board. I mean, if you have an embarrassment of riches in
that situation, fantastic.
But that's not the reality.
So we don't get... You don't have a way better X-ray telescope sitting in the wings?
Right there, no.
Come on, 20 years ago?
Well, that's expensive.
1989?
It's expensive.
The Macintosh was 45 years old.
You have to take turns.
There was no smartphones.
But Chandra is still cutting edge.
It's still an amazingly...
It's just an incredible piece of equipment still. I mean, they had to smooth Chandra's still cutting edge. It's still an amazingly, it's just an incredible piece of equipment still.
I mean, they had to smooth Chandra's mirrors so much.
Like all the technology that was necessary to create that
has then actually led to all of these fantastic
spinoff technologies that we get to benefit from every day
in medicine, in imaging, in agriculture.
Focusing x-rays is a big thing.
I mean, it's huge.
Like there was so much work
that had to go into figuring that out.
So I feel like we can
write off that for a while.
I'm just saying,
don't put Tandor
in an early grave.
It's doing beautifully.
Okay.
All right.
That's very cool.
Very cool.
All right.
Do we have time
for another one?
Can I end with a story?
Oh, a story.
Story time.
Story time.
Okay.
Let me get rid
of these stupid questions.
Okay.
Go ahead. So there's a guy. His name is me get rid of these stupid questions. Okay. Okay. Go ahead.
So there's a guy.
His name is Riccardo Giacconi,
generally considered among us to be the father of X-ray astronomy.
Okay.
And he knew that if you want to see X-rays,
you have to do it from above the atmosphere
because X-rays don't make it through the ozone
and other particles in our atmosphere.
So you need something above the atmosphere if you're going to see the universe in x-rays.
Well, if you're going to launch something, it can't be too heavy because it's expensive to
launch heavy things. It's got to be light. It's got to be portable. So he was one of the founders
of American Science and Engineering, a company based in Cambridge, Massachusetts, that pioneered small portable x-ray detectors. When was this? In the 1960s.
What was going on in the 1960s? Oh, they were hijacking planes to Cuba.
People were taking guns on planes. Congress said, we need a way to stop guns getting on planes.
We need x-rays at airports. Bam! We have American Science and Engineering
providing the first x-ray detectors at airports,
enabled as these portable devices
because they're trying to put them on a satellite into orbit.
Wow.
And he would ultimately get the Nobel Prize,
as Kim had introduced him earlier in the show.
And I was on the committee, the presidential committee,
that awarded him the Presidential Medal of Science.
And when you get the Presidential Medal of Science,
everyone goes to the White House.
I get invited to the White House.
And here comes Riccardo Giacconi to the White House
to get the Presidential Medal of Science.
And you go through the security house
before you get into the White House itself. And you go through the security house before you get into
the White House itself.
And what does he walk through?
An American Science
and Engineering metal detector.
Wow.
And it was like,
And does he have a metal hip
or a plate in his head?
That would be awesome.
And then they tackle him
to the ground.
I just thought that was so,
it brought closure
to the fact that the president is being protected by technology
that he helped pioneer,
and he's getting the President's Medal of Science
for having pioneered just that.
X-ray astronomy is a gift that keeps on giving.
Well, there you go.
I tell that story in Accessory to War
with my co-author, Avis Lang.
Nice.
And just, it's astronomy technology
affecting security.
It's one more way
where our penchant
for trying to destroy
one another
has led to a modern day Marvel.
Happy note.
We got to end it there, Chuck.
Yeah.
So, Kim Arcand,
thank you for coming
on Star Talk.
Your first time.
I hope we can get you again.
You're not that far away.
No, not at all.
You're in Providence.
Yep.
Providence, Rhode Island.
Indeed.
Yes, yes.
And so, great to have you on the list.
Thanks.
Chuck, always good to have you.
My pleasure, Neil.
You've been listening to, possibly even watching, StarTalk, Cosmic Queries X-Ray Astrophysics Edition.
I'm your host, Neil deGrasse Tyson.
And as always, I bid you to keep looking.