Sounds of the Cosmos with Kim Arcand
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Speaker 2 I'm completely charmed that you can take a picture and listen to it. You can take a sound and look at it.
Speaker 2
This is mixing up our senses for the greater good of science. Oh, I'm sorry.
I couldn't hear you. I was listening to the universe.
Speaker 2 Coming up, Kim Arkand, data sonification expert for the Chandra X-ray Telescope, returns to Star Talk.
Speaker 2 Welcome to Star Talk,
Speaker 2 your place in the universe where science and pop culture collide.
Speaker 2 Star Talk begins right now.
Speaker 2
This is Star Talk. Neil deGrasse Tyson, your personal astrophysicist, and we're going to do cosmic queries today.
Chuck. What's up, Neil? When we do cosmic queries, you come supplied with the queries.
Speaker 2
With the actual queries. With one of our regular, is she a regular yet? She is a regular at this point.
She's been on four times, something like that. Easily, yeah.
Yeah. The one and only Kim Arcan.
Speaker 2 Kim, welcome back to Star Talk.
Speaker 3 Thank you. I feel like I need a jacket or something, like they do at Saturday Night Live, you know?
Speaker 2
She puts the pressure on us now. A five-timer.
Yeah, we're gonna have to get her a master's jacket.
Speaker 2
A yellow or gold jacket. All right, she just, all right, maybe we gotta do something about that.
Okay, thanks for that idea. So, Kim,
Speaker 2 you're a visualization scientist,
Speaker 2 emerging technology lead for the Chandra X-ray Telescope, which is, is that run out of Harvard Smithsonian Center for Astrophysics?
Speaker 3 Yes, the Tanarks Observatory is a NASA mission that is run for NASA by the Smithsonian. So I am up here at the Center for Astrophysics in Massachusetts.
Speaker 3 Well, though I'm not technically there right now, I am. That's my usual base.
Speaker 2
Apart from the cool stuff you do, what has made your career unique, you have pioneered data sonification. Just remind us what that is.
We spent a whole show on that in our archives.
Speaker 2 People can dig that up. But just for now, just remind us what you do there.
Speaker 3 Yeah, so my whole job is just about thinking about our data differently and figuring out other ways that we can visualize it, translate it into sound, which is sonification, bring into tactile or otherwise like haptification types of environments through 3D printing or vibrational response and just trying to really dig down into how we represent our data, whether for scientific analysis or for communication and public engagement, both of which are very, to me, worthwhile things to do.
Speaker 2 Yeah. So if you're shifting the sensory experience, this could be highly useful for people whose sensory
Speaker 2 physiology doesn't match that of what is average.
Speaker 3 Exactly. We work very closely with the blind and low vision community, particularly on the data sonification and some of our tactile materials as well.
Speaker 3 But all of this grows out of like these are valid tools of scientific expression and analysis, right? So sonification is actually a tool used in the sciences to work with data.
Speaker 3 It's used by scientists who are blind or low vision, but also by sighted scientists because you can just think, right, if you're a sighted scientist and you're looking at an image all the time and it's very familiar to you, you can almost become numb to it, right?
Speaker 3 The data is the data, but you can, when introducing new senses or new experiences, new modalities, it can just like rewire your brain a little bit different, right?
Speaker 3 So something that you might have looked at a lot or felt familiar with, it can kind of like open a new window. And I love that, that possibility for additional exploration.
Speaker 2 Now, it's not an accident that you're working on a telescope that specializes in x-rays. None of those bands of light are visible to the human eye.
Speaker 2 But in principle, someone such as you could exist for every telescope that's out there.
Speaker 2 Because even for visual imagery that we all just take for granted, that we can see color photos, people who are low vision or blind can't see them, and that could still benefit from sonification, correct?
Speaker 3
Correct. Yeah.
So, I mean, Chander really has been the impetus for this for me because I started thinking very early on in the mission, this is all invisible data, right?
Speaker 3 Humans cannot naturally see X-rays. And the same goes for the infrared data that the Webb Telescope looks at and for radio data and even the data that the Hubble Space Telescope is gathering, right?
Speaker 3 We are not taking space selfies of the universe, like we are translating that data into a visual representation through extreme magnification, through the translation of these different kinds of light.
Speaker 3 And so that sort of possibility that this data does not only have to be visualized, but there are other ways to explore. It just gives you a new kind of like sandbox to play in.
Speaker 3 And when you're particularly in tune to how other people understand data, process data, think about data, it just allows you to try some things that can be really cool in and of themselves, right?
Speaker 3
It's like that cut curb effect. You cut a curb and you can use it if you're a parent with a stroller.
You can use it if you have a wheelchair. You can use it if you're on crutches.
Speaker 3 You can use it if you're on a bicycle, whatever, right? It benefits multiple people.
Speaker 3 And I think that's one of the really exciting things about thinking of your data differently and trying different multimodal approaches.
Speaker 2 It also gives you an opportunity for
Speaker 2 different manipulation of the data when you're working with it.
Speaker 2 So, what came to my mind the first time I read, you sent us an article
Speaker 2 last year.
Speaker 2 And
Speaker 2 when I was reading it, I thought about
Speaker 2 sound editors. And sound editors don't edit using sound, They actually look at the wave pattern of the sound
Speaker 2
on the screen. That's where they cut it.
And that's where they make all their decisions to make their edits. So that's kind of in reverse of what you're doing.
Speaker 2 But, you know, at the same time, it's the same principle. It's like you can manipulate the data differently because you're quote unquote looking at
Speaker 2 because in the old days, they'd have these reel-to-reel soundtracks and they would be listening for where the sound would drop.
Speaker 2
And then they'd splice it, cut it, tape tape it back together to make the final product. Right.
Yeah. Yeah.
So, yeah, it's very cool.
Speaker 3
Yeah. And we've actually had an artist take a sonification and reconstruct an image from it.
That piece I think is in a museum outside London right now. And I just thought that was so creative, right?
Speaker 3 To take the sound that was produced with that data, but then to essentially backstep it until they had an image.
Speaker 3 And their resulting image was meant as an artistic interpretation, but it was not super far from the original. Like it had strong elements of that original data.
Speaker 3 And I just, I love those kind of ideas of just play and creativity, which seem like they would be bad words of the workspace, right? They're really not.
Speaker 3 It's just about opening up your brain a bit and just trying to think about things a little differently.
Speaker 2 So I have one issue with you, if I may. Uh-oh.
Speaker 2 Here we go.
Speaker 2
Here we go. Not your fault.
Not your fault. So in the movie Contact, I love that movie.
Which was based on the novel by Carl Sagan.
Speaker 2
The lead protagonist, Ellie Arraway, was her name, the character's name. She was an expert in the search for extraterrestrial intelligence, which is normally done with radio telescopes.
And she
Speaker 2 would sonify the radio signal into headphones, and she'd be listening on headphones to the radio signals. And here's my issue: the word radio
Speaker 2 people think of as sound,
Speaker 2
but radio waves is electromagnetic energy. Right.
And so
Speaker 2 it makes people think that the aliens were sending us sounds,
Speaker 2
but they were not. They were sending us radio waves that we converted to sound.
We end up making a one-to-one correspondence between the word radio and sound. Right.
Speaker 2 And that movie didn't help disavow people of that association. So I blame you for that.
Speaker 3 That is one of my favorite space movies, but that is one issue that has always stuck out for me as well.
Speaker 3 However, I will also say, you know, it is very commonly thought that these images are like direct snapshots as well.
Speaker 3 So it's just about being very transparent in what you're doing, really describing what you're doing in a way that's clear and makes sense, and just kind of reiterating, you know, we are not capturing space selfies and we are not capturing like space recordings.
Speaker 3 These are translations, like you might translate English to Mandarin, right? You have to have a way to interpret it.
Speaker 2 So remind us,
Speaker 2 this is a Cosmic Query, so I want to make sure we get to the questions, but catch us up again on what the Chandra X-ray Telescope does, which is one of the great observatories.
Speaker 2 along with Hubble and a few others, each in their own band of light. Remind us what Chandra does that other telescopes can't do and what it sees that other telescopes can't see.
Speaker 3 Yeah, so Tander is kind of like part of that super friends team, if you will, with Hubble, with Webb, with these other telescopes.
Speaker 3 And Tander is our sharpest X-ray view, right, of that high-energy universe. It has still to this day, after 26 years of being in operation, you know, it's looking at things like exploding stars.
Speaker 3
It's looking at things like clusters of galaxies and the hot gas that envelops them. It's looking at young stars and the sort of...
X-ray temper tantrums that they can have.
Speaker 3 It's looking at all of these very energetic phenomena across the universe. It's exciting because tander has such exquisite resolution.
Speaker 3 It's half of an arcsecond and arc second is just like a tiny unit of angular size. If you like, you know, 3,600 arcseconds in a degree essentially, you're just looking at one half of an arcsecond.
Speaker 3 It's kind of the equivalent of if you're looking at a dime from a few miles away, right? It's really amazing.
Speaker 3 So that kind of helps tander be, if I could refer to my past as a biologist, as a microbiologist, it kind of allows Chander to be like the X-ray microscope of the universe.
Speaker 3 It really can dig down very deep, very sharp.
Speaker 2
Very cool, very cool. Yep.
Love that analogy.
Speaker 3 It's like Chander's resolution is comparable to Hubble's, but it's looking at high resolution. It's looking at those high resolution
Speaker 3 the x-ray photons in the universe, of which there are not as many as there are.
Speaker 3 You know, the stars, for example, though they give off X-ray light, they are not giving off as much output as they would for infrared or optical light, typically, unless something really wild is happening.
Speaker 3 So there tends to be a slight, you know, darth of x-ray photons in the universe, which just makes it really challenging to do. And Chandra's engineering was such that you can't use normal mirrors.
Speaker 3 You have to use these barrel-shaped nested mirrors, of which Chandra has four pairs, so that you can just kind of skim the X-rays down. It's like it's grazing incidents.
Speaker 3 It's like skipping a rock across a pond, right? And that lets lets you then focus them down at the detectors to be able to capture that.
Speaker 2 That itself was an engineering discovery, perhaps, right?
Speaker 3 Oh, yes.
Speaker 2
That you can focus x-rays that way. Because, you know, we have a lens, you put light through it, you can make an image on the other side.
That's what a magnifying lens is.
Speaker 2
X-rays don't do that in glass. You got to be more inventive about it.
I just like the fact that you said it was part of the Super Friends. Oh, the telescope.
Speaker 2 And you made a DC reference, and the only DC character that has X-ray vision is Superman. So that makes you guys the Superman of the Super Friends.
Speaker 2 I guess so. I see what Chandra did there.
Speaker 2 Chandra itself. Plus,
Speaker 2 you guys are good at finding black hole,
Speaker 2 black holes that are in binary star systems.
Speaker 3 Yes, Chandra is really a black hole hunter.
Speaker 2 Why is Chandra so good at finding black holes?
Speaker 3 Well, the exquisite resolution and the ability to peer through that gas and dust that can clog the hearts of galaxies that Chandra gets to see.
Speaker 3 So Chandra is looking at things like Sagittarius A star, the supermassive black hole in our own galaxy. It's looked at that over and over and over again.
Speaker 3 And kind of one of the benefits of a mission with such longevity is that you get to look at something over time and like build and build and build that data for a really deep snapshot.
Speaker 3 And so with like Sagittarius A star, like we've seen it snacking on small snacks, like a little asteroid here and there, an after-school snack.
Speaker 3 We've seen it like, you know, devouring a larger Thanksgiving size meal with a, you know, a big fat star, right? We've been able to see that
Speaker 3 different things happening over time, which is, I think, really lovely. But yeah, black holes are one of my favorites.
Speaker 2 I mean, but it's rendered visible because as it gets very hot, spiraling down, it radiates x-rays. That's how, that's the mechanism, correct?
Speaker 3 Exactly. And again, that's that high-energy phenomenon, right?
Speaker 3 There's not as many high-energy phenomena, things that are, you know, burping out super super high energy particles, things that are exploding, things that are colliding as there are, say, normal stars, but there's still an awful lot to look at throughout the universe in X-ray light.
Speaker 3 So there's just always something new.
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Speaker 7 This is Ken the Nerdneck Zabara from Michigan and I support Star Talk on Patreon. This is Star Talk Radio with Neil deGrasse Tyson.
Speaker 2 How about pulsars? Are they something that you guys pick up a lot on?
Speaker 3 Yes, pulsars are fabulous because they're kind of like, i kind of think of them as like you know zombie stars stars that have kind of come back to life a star that was you know massive its core collapsed it's just star explodes it burps all over the place that's just amazing and what's left is this star core about the size of manhattan perhaps and it can spin really fast um and that kind of again incredible high energy phenomena is a perfect thing for Chandra to look at.
Speaker 3
I can't even count. I'd say the the number of pulsars Chandra has looked at.
I'd actually be interested in that. But a lot, a lot.
Speaker 2 If we didn't have an X-ray eyes on the skies, we would have no idea these phenomena were happening.
Speaker 2 Mostly, I mean, unless it also gave us visible light or infrared, there's a certain blindness we have without an X-ray telescope.
Speaker 3
Exactly. I like to liken it very fair.
I mean, I like to liken it to like the Wizard of Oz scene when the tornado is over and
Speaker 3 Dorothy steps out of the black and white, opens the door and it's like this technicolor universe now.
Speaker 3 To me, Chandra and other telescopes across wavelengths are like providing us that gorgeous technicolor experience that we didn't have access to 20, 30 years ago.
Speaker 3 Like this is relatively new that we're able to like get more and more of the color of that universe, if you will. And now we get to go down the yellow brick road and it's really lovely.
Speaker 2 I first saw Wizard of Oz on a black and white TV. so I had no idea that anything different happened when she stepped through the door.
Speaker 3 Oh, wow, really?
Speaker 2 Nothing was in color for me on a 19-inch black and white living room TV. That's really cool.
Speaker 3 So did the movie feel boring without the colour?
Speaker 2
No, I didn't know that there was something. Yeah, there was nothing.
You weren't missing anything because there was nothing to miss.
Speaker 2
It's a black and white. I got a black and white TV.
Why do I think anything different is going to happen? Right.
Speaker 3 Well, that's how we were before we had all these telescopes, too. We didn't know what we we were missing, right? We didn't know what we didn't know.
Speaker 2
You didn't know what you didn't know. Right.
Is the universe ever going to get a brain and a heart?
Speaker 2 I don't know.
Speaker 3 That's a good question.
Speaker 2 Yeah, they put that on the list.
Speaker 2 So, Kim, Chandra's also studied Ada Carina, which is quite the
Speaker 2
spot for action in our galaxy. Nice.
Yeah, tell me more about that.
Speaker 3
It's very near to us. It's only like 7,500 light years away.
So that is in our sort of local galactic neighborhood, if you will, well within the Milky Way.
Speaker 2 Afternoon trip to the store. In afternoon.
Speaker 3 Exactly. The cosmic store, but yes.
Speaker 2 You can Uber there.
Speaker 2 Is Ada Carina the product of a dead star, or is it a star-forming region? I always forget which that is.
Speaker 3 The general area around it is a star-forming region, but the star system itself is like a massive binary, though it could be, there could be three.
Speaker 3 I'm not sure if it's two or three these days, but there's at least two pretty massive stars, like I want to say 30 and maybe 90 million times the size of our Earth.
Speaker 3 So very large stars that are like hanging out together.
Speaker 3 And one of them goes through these massive outbursts, which created like a near supernova event because it was incredibly bright and it was witnessed from Earth in the 1840s-ish.
Speaker 3 It was called the Great Eruption.
Speaker 3 And then it dimmed. And now people think that it could explode because it has been losing its material, if you will, over time.
Speaker 3 And telescopes like Chandra, like Hubble, and others are able to monitor it over time, which, again, for longevity missions really provide you with a fantastic way to see that change over a human.
Speaker 2 time scale.
Speaker 2 No substitute for that baseline.
Speaker 3 Yeah, exactly. Like the course of my son's life, essentially, like we can see changes in that star.
Speaker 3 And Chandra is detecting like the really powerful stellar winds from that explosive or near explosive event.
Speaker 3 And then Hubble is capturing some of that cooler gas and dust that's kind of created this bipolar structure
Speaker 3 called the, I think it's the homunculus nebula,
Speaker 3 right kind of around the star system. And so we do have a 3D model of that that folks can take a look at on the Chandra website, chander.si.edu slash 3d print.
Speaker 2 Oh, interesting. And can we rotate it on the website as well?
Speaker 3 Yes, you can. There's a little video that plays it going around.
Speaker 3 And so you can kind of see there are these two lobes of material and then the chander material, which is not in this 3D model, kind of hugs it.
Speaker 3 It kind of looks like a giant space croissant of high energy material wrapping around the homunculus. And then the two stars, or maybe three, are buried like inside.
Speaker 2 Did she just say space croissant? I know. And I'm so hungry right now.
Speaker 3 I know. I'm kind of hungry too, which is why I came to mine.
Speaker 3 But it's like a hug. It's like a hug around
Speaker 3 the homunculus, which I think is very cool.
Speaker 3 But so these types of 3D models, like these are actually done for scientific analysis, and then we're able to 3D print them so that scientists can study them and understand them and display them.
Speaker 3 But also, importantly, so people who are blind or low vision or people who just really like to study tactile or learn tactile have access to a different way of knowing.
Speaker 2 So, okay, so I think we let's get on to some Q a here all right
Speaker 2 you got the list uh that and guess what they are ready to go our listeners i'm so impressed with the questions that my people ask listen these people are not playing around yeah yeah i'm ready uh-oh yeah yeah all right let's start off they've been cued that kim is our guest as a matter of fact they completely know this okay these are specifically questions for you kim okay
Speaker 2
love that yeah the audience knows who you are and they're very excited to ask you questions. All right.
So this is Russell Harvey. Russell is from Colorado and he says,
Speaker 2 how does sonification of X-ray data from Chandra help us understand cosmic phenomena like black holes or supernovae
Speaker 2 in different and new ways?
Speaker 2 So what are you doing
Speaker 2 finding that is proprietary to you
Speaker 2 that you can say, oh, yeah, that was Chandra. That's an important question because
Speaker 2 otherwise you're revealing just what is already known that a sighted person would see.
Speaker 2 So do you have some insights there?
Speaker 2 Yeah, like some gossip, like, girl, you know, I heard from Chandra. You know what I heard from Chandra?
Speaker 3 Well, I can say, well, we start out generally, right? So sonification helps us pick out patterns in data that can be hard to see.
Speaker 3 So they're often particularly helpful in things like studying gravitational waves or understanding variable stars and that sort of thing, where you have to pick out patterns in a lot of data that can be hard to see in only an image.
Speaker 3 So you can think of like rhythmic flickering.
Speaker 3 So for black holes at least, there have been like additional thoughts about things like the Perseus cluster, because when that result of the Perseus cluster that showcased that there was this massive, supermassive black hole at the core burping out into the hot gas around it, causing these sound waves, these pressure waves, which are sound waves, and that that note is about a B flat, about 57 octaves below middle C.
Speaker 3 Well, listening to the soundification, like bringing that note, if you will, back up into the realm of hearing by taking the image and scanning those waves in the image so that you can hear them through sound.
Speaker 3 What I have heard is that researchers have noticed that there were additional ripples that had been missed originally.
Speaker 3 So that is something that I haven't seen a paper on it or anything like that, but I have heard discussions that that is the sort of thing that could be really useful to do more of this idea of being able to find small details that either wasn't as obvious in the visual or numerical data or you would have overlooked it.
Speaker 3 Exactly. And that's the thing, like when you look at something a lot or if you're just staring at something, you're getting all of the data at once.
Speaker 3 When you're listening to it, you're actually given the gift of time, right?
Speaker 3 So you have your brain responds in a different way because you're getting that data sort of parsed out to you based on the tempo of the sonification.
Speaker 3 And I think that's kind of an exciting space to do more experimenting.
Speaker 2 And just to remind us, the sonification is basically a scan of the image where each row has some acoustic, as the scan comes across a star or an object that has X-ray flux.
Speaker 2 Does the pitch go up or just the volume go up? What typically would happen there?
Speaker 3 Yes. So it's a mathematical scan across the image or from the center out or all of that.
Speaker 3 And like pitch, tempo, volume, instrument choice, like all of those are the variables that we'll use in order to describe.
Speaker 2
Instrument choice. I love it.
Look at that. I want a saxophone in space.
Speaker 3
Well, we do. Yeah.
So if you have like a heavy-duty data set that's got a lot of different kinds of light, choosing disparate instruments to assign to the data that you can really make
Speaker 3 you can really tell what's playing when
Speaker 3 lets you to kind of help identify different parts of the image or the information that you're trying to decode.
Speaker 2 Is there any use of an oboe
Speaker 2 or a didgerido? Yes.
Speaker 3 I would say all instruments welcome, including voices.
Speaker 3 Yes, I think all instruments are welcome.
Speaker 2 What a great answer.
Speaker 2
And thank you, Russell. All right, this is Hugo Dark.
Dart. Pardon me, Hugo.
Hugo Dart. Hello, Dr.
Tyson, Dr. Arkand, Lord Nice.
This is Hugo Dark from Rio de Janeiro, Brazil.
Speaker 2 Ah, chuki boom. Anyway,
Speaker 2 you realize they have one of the largest aerospace industries in the world in Brazil. And
Speaker 2 all you can do is shake your ass
Speaker 2
when you say Brazil. I did not know that.
You know why? Because in Carnival, they do not show aerospace.
Speaker 3 That is a valid point.
Speaker 2
Yeah, just valid. Yeah.
Okay, he got me on that one. Okay.
Speaker 2 Hugo says, I'm with my seven-year-old daughter, Olivia, who is also a very very big star talk fan so hello olivia uh here's our question to both of you
Speaker 2 why
Speaker 2 will space freak us out oh because you have a book
Speaker 2 kim has a book coming out yes that's such a sweet question
Speaker 2 called why space will freak you out oh get out and it's a book
Speaker 2 that is intended to be like parent-child combo exactly like a family reader kind of thing.
Speaker 2 How much you pay Hugo to
Speaker 3 lovely. I mean my goodness.
Speaker 2 Kim, this is your ninth book. So tell us, tell us about that book.
Speaker 3
Yeah, this is my first like sort of, you know, kid family reader type of thing with my amazing co-author, Megan Watsky. And it's kind of, it's meant to be a little fun.
My husband loves horror movies.
Speaker 3
I think it's because he was born on Halloween. And so I'm not a fan of horror movies, but he watches a lot.
And I think it just kind of gone into my brain. So my humor is a little darker,
Speaker 2 I would say.
Speaker 3 And this idea of like finding fun in the creepy and the weird and the strange and the exotic and the universe is something that's just kind of been filtering in. So
Speaker 3 it's a fun look at things because it's like what is weird and creepy in our own solar system, in our own galaxy, and then like well beyond.
Speaker 3 So you can think of things like exoplanets, like the exoplanets that we have found so far, some of them are so gosh darn weird, like, you know,
Speaker 3 worlds where it rains glass sideways at like 5,000 miles an hour, lava worlds, frozen worlds, dead worlds going around zombie stars. I mean, it just, it sounds like science fiction.
Speaker 3 And so it was just kind of an opportunity to think of some of those fun things, those weird things, those freaky things, and just talk about them in a way that's hopefully not too scary.
Speaker 3 But I guess to answer the question, like, really, it's just that space is huge and mind-boggling and extreme and weird.
Speaker 3 And we're very lucky to live here on our cute little rocky planet where things are relatively,
Speaker 2 well, not weird. Kind of shape.
Speaker 3 Comparatively speaking.
Speaker 2 Comparatively speaking.
Speaker 2 Speaking of which, here's a follow-up from Olivia. Okay, actually, it's from me.
Speaker 2 I've read this or heard this someplace, but please tell me, what is,
Speaker 2 how far do we have to go towards the sun or away from the sun where we don't have this planet anymore? Venus is to our left and is 900 degrees. Mars is to our right, once had water and does not.
Speaker 2
So we are sandwiched in between two wholly inhospitable planets. Right.
So you asking what
Speaker 2 you asking me now? So that's what I'm saying.
Speaker 3 Could we nudge like a mile to the left or a mile to the right?
Speaker 2 That's what I'm saying. So if you
Speaker 2 how far could we go towards Venus and still live? And how far how far could we go towards Mars and not freeze?
Speaker 2
There are surely people who know this. I don't have that answer.
Okay. But Earth has a certain recovery mode that
Speaker 2 could make up for small changes. Oh.
Speaker 2
It can find a new equilibrium where it is, where it can still function, but not too far. You don't want to fresh your luck.
Kim, do you have any insights there?
Speaker 3 No, I mean, it's a great question, and I'd kind of love to know the answer. But
Speaker 3 I mean, I feel like some
Speaker 3 biology side of me is kind of like some life forms on Earth, probably not humans for a long time, could adapt to slightly more extreme temperatures either way. Like we've seen with tardigrades, right?
Speaker 3 Water bears, they can live in pretty extreme environments.
Speaker 3 So there's some possibility that if we nudge left or right, I'm using, which are not the right directions, but you know what I mean, closer to Venus or closer to Mark,
Speaker 3 that there would be something that could adapt and survive that.
Speaker 3 But I feel like humans would probably not be on the list for very long because food sources, other things would be affected so quickly, at least I think. Okay.
Speaker 2 And by the way, there is a unique left and right in an orbit. Just the same way Rive Gauche, that's the left bank in France of the River Seine, or whatever the the river is there.
Speaker 2 So
Speaker 2 the left is the shore that is on your left when you're moving with the river.
Speaker 2
That's a unique left. That's a unique left.
Yeah, and then a unique right. So when I say Venus is on the left,
Speaker 2
we are the river of Earth passing between Venus and Mars. Sweet.
That's pretty.
Speaker 2 Only Neil can make
Speaker 2 only Neil can make an orbit sound like sex.
Speaker 2 You know?
Speaker 2 All right, here we go. This is
Speaker 2 Jeffree C.
Speaker 2 He says, hello, SMEs.
Speaker 2 My question. SMEs, what's SMEs? I don't know.
Speaker 3 Subject matter experts.
Speaker 2 Oh,
Speaker 2 right.
Speaker 2 So he's just talking to YouTube.
Speaker 2
He was like, screw that up. That's an SMEs.
I never heard it about it. SME, yeah, subject matter expert.
Okay. He says, thank you, Kim, for zoom me in on that.
Speaker 2 He says, my question straddles the line between science and engineering.
Speaker 2 My understanding is that X-ray observatories employing grazing incidence mirror designs primarily to minimize scatter and reflection losses rather than to optimize for minimal wavefront distortion.
Speaker 2 To me, achieving diffraction-limited imaging in X-rays sounds wicked awesome, but it seems like current current X-ray telescope designs prioritize maximizing the collection of photons at the detector instead.
Speaker 2 What's the reasoning behind that? Please teach me more. Now, first of all, let me just say this: don't nobody need to teach you nothing
Speaker 2 who teaches this guy.
Speaker 2 Who's going to teach you? Listen to that question.
Speaker 2
This guy just gave us the anatomy of the telescope in such a way. That's what he did.
You show off, you big fraud, show up. Like, but please tell me how exactly
Speaker 2 do we get the photons to the detective? And you know damn well, and by the way, I love it. What I love about Berchie Bandu is
Speaker 2 the photons on a detective.
Speaker 2 But Mima a moment ago explained that she didn't use the word grazing, but that's what it is. Yes, she was talking about it with the mirror.
Speaker 2
The conical, it's skimming. Skimming.
With it, with the rock on the, on the
Speaker 2
fellow raises a very important point. Jeff from Boylston, Massachusetts.
We're playing with you, Jeff.
Speaker 3 Which, by the way, I have to give the shout out to Massachusetts fellow New Englander with the wicked awesome. That was perfectly, I mean, I just love this audience so much.
Speaker 2
Yeah, wicked is a very New England expression. Oh my God.
Yeah.
Speaker 2
Ah, yeah, very wicked. Wicked smile.
Wicked smile. That came out.
Speaker 2 Very wicked smile.
Speaker 2 She came here in a calf.
Speaker 3 But so I guess I would say, like, there's kind of two issues at hand.
Speaker 3 I talked about a little bit earlier already, so maybe it's sort of helped, but X-ray photons, very energetic, very incredibly difficult to focus, right? This is high energy.
Speaker 3 It is a bullet going through a wall kind of thing.
Speaker 3 So because of that and needing the grazing incidence and having to like skip down across a pond, as we talked about earlier, there's two things to consider. The physics and the engineering limits.
Speaker 3 I'm not an engineer, so I cannot speak to this in like detail.
Speaker 3 But I will just say that like we already for Chandra had to have mirrors like really polished incredibly smooth like if you um smooth down colorado pike's peak would be like maybe an inch tall right like it's a really incredible accomplishment or feat uh that american engineers had to do just to get the chandra mirrors to like you know near atomic levels, never mind what you would need for that kind of diffraction limiting imaging, which would be like atomic scale perfection.
Speaker 3 And of course, like the alignment in them as well, and then sending it up into space into that like harsh, cold environment where it would have to operate like perfectly.
Speaker 3 So there are some engineering limits there that I would say.
Speaker 2 USA, USA. Yes.
Speaker 3 Yes. But also, it also goes back to like that photon-starved universe that I mentioned earlier in the show, right?
Speaker 3 X-ray sources are typically a bit fainter than all of the optical or all of the infrared data that can be gobbled up by by these light buckets, right?
Speaker 3 And so the idea of building an observatory that would be able to collect enough of them, that is kind of like, that has been the priority, right?
Speaker 3 So maximizing your collecting area and getting, I don't want to say good enough, because Chandra's resolution is incredible to me, but like being able to get there with Chandra's half arc second resolution was an absolute feat.
Speaker 3 So getting to go beyond that, it really becomes like true engineering and physics issues that have to be fixed by bigger brains than mine. So, all I can say is wicked, awesome question.
Speaker 3 I don't exactly have an answer, but I love that you asked it.
Speaker 2
But it comes down to, like you said, you don't have all that many photons to work with. So, you can't prioritize resolution.
What good is your resolution if you didn't have the photons to collect?
Speaker 2 You got nothing to collect.
Speaker 2 So, I'd have to agree, or to what was supposed there, that it's an engineering decision to maximize
Speaker 2 your access to photons than the resolution itself, even though you still have very good resolution. Right.
Speaker 3 Definitely.
Speaker 2 Yeah. Okay.
Speaker 2 Well, by the way, Jeff,
Speaker 2 we love you, you big show off.
Speaker 2 Definitely.
Speaker 2 That was a great question. All right.
Speaker 2 This is
Speaker 2
Mario Funes, I think. Funes.
Or funes?
Speaker 2
Mario. I'm going to go with Funes.
How do do you spell it f-u-n-e-s funes funes funes yeah all right mario fun
Speaker 2 okay
Speaker 2 this is mario from fort lee new jersey way right across the river here um across the moat oh man that was that was rough bro
Speaker 2 why you got to do that fort lee is across the hudson river from manhattan yes okay it is but i love the moat because you know i live on the other side of the moat too x-ray astronomy often relies on assigning colors to energy bands that are invisible to the human eye.
Speaker 2 How do you strike a balance between scientific fidelity and aesthetic impact when choosing color palettes? And have audience reactions ever led you to rethink
Speaker 2 your visualization approach?
Speaker 2
Does that also apply to sound? How do you get your baseline for sound? That's not what the person asked. Okay, but I'm just throwing that on top of Mario's question.
No,
Speaker 2 pay the Patreon fee and then you can ask
Speaker 2 a question. So that's $2.50.
Speaker 2 I can give you $25. I gotta do two for one.
Speaker 2 A two for one.
Speaker 3 No, this is a great question because I love talking about this topic because it's so useful when you can kind of underline the idea that these are visual representations of data that is invisible to human eyes, right?
Speaker 3 And we're capturing that information.
Speaker 3 We are translating it into the visual representation, but those are human beings doing that process using software that's been coded by humans and making choices that that human thinks are the best choices but there's obviously going to be a wide range of possibilities so for color palette specifically we have pretty much settled on like an RGB red green blue for low medium and high energies for our color coding typically so that means often tander images if combined with say infrared or optical kinds of data tander will often be colored in like blues and purples and then say the Hubble data in the greens and the web data in the infrared in the reds right that's often what we're doing because we have found that that does tend to make an image that is both aesthetically pleasing but does align with that scientific information.
Speaker 3 However, there are many times when the color palette has to get thrown out of the window because the science says so, right? The data says so.
Speaker 3 If you're getting a massive data set and you are trying to pick out different kinds of chemical emissions in a supernova remnant and you're codifying where the pockets of iron and the silicon and the sulfur and the calcium and the oxygen are, you have to go into a different type of color scheme.
Speaker 3 So, I guess the shortest answer is that we do have a kind of standardization, but the science drives the story, the science drives the visual, and then we adapt based on the needs of that.
Speaker 3 Now, to the last part of the question about rethinking visualization approaches. Yes, so I've actually done studies because I like people
Speaker 3 as much as I like space.
Speaker 3 I like to learn about both of those things because we are not just studying space as robots, like we are humans studying the universe around us.
Speaker 3 And so to me, at least, it's just as important to understand human perceptions and human understandings, human meaning-making, right, of that type of data.
Speaker 3 So, we have done studies on looking at how humans respond to our visualizations based on different kinds of color codes and different kinds of aesthetic appeal.
Speaker 3 And the interesting result was that it didn't actually make a difference, even if some of the color schemes would have been like a bit like ugh to me.
Speaker 3 In general, any color scheme that still got across a data that was described like what we were doing, that was the winner. And it didn't exactly matter how it looked.
Speaker 3 So people appreciated being able to understand what the colors meant, I guess, is the point.
Speaker 3 Now, there has also been a case that I remember so so specifically when it came time to do the bullet cluster, which is a cluster of galaxies and kind of like the textbook example with Chandra and Hubble that helped show this direct proof of dark matter.
Speaker 3 It showed the separation of the hot gas from Chandra and then the normal matter,
Speaker 3 sorry, the normal matter, if you will, from all of the dark matter, which was gravitationally mapped, right?
Speaker 3 And it was all kind of with a Hubble data showcasing where the galaxies and everything were located.
Speaker 3 And for that image, typically the Chandra data would have been in blue as the highest energy in the data set. But when we first made the image, we did a little like testing of it.
Speaker 3 And it just, when trying to sell the story of all of this hot matter, the separation from the dark matter, it just was not vibing for people.
Speaker 3 So we actually inverted the color scheme, put Chandra in like the pink-reddish color, and then put the dark matter map in the blue.
Speaker 3 And that worked better for people for that specific scientific discovery or scientific
Speaker 3 expression, and has since been kind of like a de facto for how we color code those examples of galaxy clusters that are showcasing the separation of normal and dark matter.
Speaker 2 By the way,
Speaker 2 for anybody interested,
Speaker 2 I don't know the name of it, but Neil gives one of my favorite explainers
Speaker 2 on
Speaker 2
how we take any bandwidth and make it so that we can look at it with our human eyes. And it is a fascinating explainer.
Oh, really? Okay. Forgotten all about that.
Yeah. It's in our archives.
Yeah.
Speaker 2 It's in the
Speaker 2
one of my favorites. Actually, really? Yeah.
You never told me that. Yeah,
Speaker 2 you did an exceptionally
Speaker 2 incredible job of that, which is redundant, but it was
Speaker 2 so clear. And it was something that secretly I never understood.
Speaker 2 I never understood. And then after that explainer, I was just like, all right.
Speaker 2 That's why they call it explainers, I guess. Yeah, I guess so.
Speaker 2 And Kim, it should be fair to declare that if you assign an RGB to a low, medium, and high-energy bands,
Speaker 2 I think we can, with honesty, say that if the human retinal sensitivity were shifted to that realm,
Speaker 2 it is the color picture you would see.
Speaker 3 Yeah, they do tend to call them true color representations in that RGB setup for that reason. I like to think of all of them as representative color, right?
Speaker 3 Like we're not the mantis shrimp being able to see all sorts of colors all over the place, right? But I do think it is fair to say that that is a more true representation. Yes.
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Speaker 2
All right, time for a few more. All right, here we go.
This is Neil Cameron. Neil says, hello, Lord Nice, Dr.
Arkan, Dr. Tyson.
Speaker 2 Neil here
Speaker 2 from Esonia, Connecticut.
Speaker 2 I'm going to keep this simple.
Speaker 2 Black hole sonification.
Speaker 2 Do they sound like
Speaker 2 or more like bloop?
Speaker 2 And... But how do you read that off of this?
Speaker 2 Oh, because he said, do they sound like Godzilla Roar or just a little bloop?
Speaker 2 So I gave him my best Godzilla Roar. I hope to work for Neil.
Speaker 2 And then the little bloop is, bloop. Isn't it just the gas swirling that we can sonify? Can sound exit a black hole?
Speaker 3
This is a great question, too. I love all of these questions.
These are the best. So, yes, so nothing can escape a black hole, right? Like sound can escape, light can escape.
Speaker 3 So yes, we are not holding up a microphone to capture sound of black holes, but black holes do have this potential, supermassive black holes in the center of galaxies, do have this potential to, as I mentioned earlier, kind of like burp out into the surrounding hot gas around it and make these pressure waves or the sound waves.
Speaker 3 And so we are taking that information, which we can see in images by the rippling, mathematically mapping it to sound. So we are choosing sounds that make sense for it.
Speaker 3 And we have done one sonification of a large population of black holes in the Chandra Deep Field South where we actually did apply like little like
Speaker 3 boop boop kind of sounds. It sounds a little bit like Imogen Heap was playing it because we were trying to showcase a massive field with thousands of black holes and we assigned the sound based on the
Speaker 3
the energy level of those x-rays. So we just chose low, medium, and high sounds for those x-rays.
So I don't know if that answers your question.
Speaker 2 And the pressure waves, they actually are literally sound waves.
Speaker 3 They are literally.
Speaker 3 So the perseus cluster is that b flat that i mentioned m87 also has them and it's lower i don't know like what the actual note equates to um but these supermassive black holes do make these sound waves right they're not singing exactly they don't have vocal cords um but they are by that sort of burping out into the area around them it's all about the environment that black holes live in right that's going to give you the interesting um whether it's a uh a burp or some other kind of you know thing that we're detecting and a big part of that question was is it the swirling of gas?
Speaker 2
And the answer is yes. Yes.
Because the black hole is otherwise not talking to you. Right.
Exactly. Chuck has the best ever imitation of a black hole.
Oh,
Speaker 2
I don't know, but I'm sure. No, no, you've done it.
Have I done it? Yes. Does it sound like this? Yo, what's up? No,
Speaker 2 it's not someone hanging out in the shadows ready to mug you.
Speaker 2 No.
Speaker 2 Oh, no. This is the black.
Speaker 2 Hey, hey, hey.
Speaker 2 Hey, I'm very hungry.
Speaker 2 Otherwise, I will lose some weight if I stop snacking in between my snacks.
Speaker 2
I forgot all about it. Well, you got a good memory, man.
The best black hole I ever heard. That is from black holes could talk.
That's what they would sound like. So long ago.
That's right.
Speaker 2 Get in myself.
Speaker 2 Okay, here we go. Rachel Ambrose says,
Speaker 2
hey there, this is Rachel from Austin, Texas. First, I wanted to say that the Chandra X-ray Deep Field Sonification has been my ringtone for over a year now.
So
Speaker 2 must be a way.
Speaker 2 Yeah. Totally way.
Speaker 3 That's cool.
Speaker 2 Do you have downloadable ringtones on your website?
Speaker 3 So I don't think we put them into ringtone format unless someone on my team did that. I didn't notice.
Speaker 2 No, she's not made of her.
Speaker 2 You can make a ringtone.
Speaker 3
But we do have little, we have little snippets of the sound available on our website to download. So, I guess if you can make your own, I never thought to do that.
It's so lovely. Wow.
Speaker 2 Okay.
Speaker 2
Very good. Very good.
She says, My question for Kim is: if you could sonify one cosmic event that hasn't been done yet, something you think would blow people's minds, please tell us what would it be?
Speaker 2 Ooh.
Speaker 3 That's tough.
Speaker 3 My instinct, because I just love every data set pretty much, but I think something in the time domain, something that we're seeing change over time, that's something that I would really like to do some of, more of,
Speaker 3 like supernovae changing over time, gamma-ray bursts clicking on and off, tidal disruption event, just anything that changes over time on like a human scale, if you will, that we've been able to capture.
Speaker 3 That's something that's kind of been on my list for a while.
Speaker 3 I don't know if it would blow people's mind.
Speaker 2 Is that because the imagery would be composing for you?
Speaker 3
Yeah, so it's already giving you like a sort of temporal flow, if you will. Like the data is changing at a rate that you could track and then represent in some interesting way.
And I don't know.
Speaker 3
I think that would be very cool. I don't know if it'd be mind-blowing, but it's definitely something I would like to try.
That would be high on my list to work on with system sounds.
Speaker 2 The time dimension is really what you're referring to there.
Speaker 2
Exactly. Yeah.
Okay. Nice.
Speaker 3 Hearing data can like draw your attention to different patterns. Like we've talked about that a little bit already that your eyes can overlook.
Speaker 3 And so being able to sonify that changing data, I think, could be really powerful.
Speaker 2
All right. Yeah.
Well, thanks, Rachel. Wouldn't it be cool if it sounded like scat music, like, you know,
Speaker 2 like a little algebra would be kind of cool. You know what I mean?
Speaker 3 It would be very cool.
Speaker 2 Yeah.
Speaker 2 Yeah.
Speaker 2 Bong, bang, bow, bow, wait,
Speaker 2 like,
Speaker 2
uh, this is Colin's Wicker. He says, hello, Dr.
Tyson, Dr. Arkan.
I'm Colin from Switzerland, and I have a question for Dr. Arkan.
Well, thanks, Colin. That's what we're here for.
Speaker 2 You'll cut nobody any slack.
Speaker 2 Has there ever been a moment? when a visualization revealed something that surprised you, something that you might not have noticed if you only
Speaker 2 looked at the raw numbers.
Speaker 3 Yes, for sure. I mean, and that is the kind of beauty of not just visualizing, but like thinking about how to visualize and what method, what platform would be best for your data.
Speaker 3 Because in supernova remnants, particularly, we've got 3D models of quite a few of them now based on observational data or
Speaker 3 computer simulations constrained by the observational data. And what that has allowed to show us, in the case of Cassipia A specifically, that there are some asymmetries.
Speaker 2 That's a supernova remnant, yeah.
Speaker 3 A beautiful supernova remnant that Chandra's looked at a lot.
Speaker 3 Some asymmetries there. And the,
Speaker 3 which you can't see, the image itself looks like so perfectly spherical and lovely. But when you break it down into the 3D model, there are some interesting asymmetries.
Speaker 3 And it also helps show that stars like Cassipia A can turn themselves inside out when they explode, because right before a massive star like that explodes, the iron is kind of really built up at the core.
Speaker 3 And when you look at the distribution of that in the supernova remnant, the iron now is actually quite far out towards the perimeter, much farther than you would expect.
Speaker 3 And so researchers were able to figure out that that star turned itself inside out. And the use of 3D modeling was really incredibly important, that type of result.
Speaker 3 So, yeah, having different ways of looking at your data can be a very powerful tool for curiosity and discovery.
Speaker 2
Very cool. Wow.
Great question, Colin. All right.
This is William Warren. He says, hi, I'm William Warren from Abingdon, Maryland.
You've created immersive VR experiences of space data.
Speaker 2 Do you think future astronauts could use this kind of visualization technology to prepare for deep space missions?
Speaker 2 Which is cool because every sci-fi movie, when they talk about going to another galaxy, they like reach and throw something into the ceiling and then the whole galaxy opens up and then they actually take their hands and like
Speaker 2 spread it and they get zoom in like we pinch on a computer screen.
Speaker 3 Yes, that I that is to me like the exciting future. Like I actually dream about whether it's astronauts, researchers, non-experts, like being able to do that type of work, right?
Speaker 3 Being able to go into an extended reality space of some sort and learn about things, train about things and whatever. But astronauts are actually already doing that.
Speaker 3 They actually use virtual reality and other kinds of extended reality technology applications in order to learn about spacecraft and like where they're going to be docking, how they're going to be docking, where things are located in their spacecraft.
Speaker 3 Special kinds of like training modules have been done with VR.
Speaker 3 It's already a very useful tool because especially if you think about astronauts having to do a spacewalk and to do some kind of complicated,
Speaker 3 you know, procedure out in space, being able to walk through it in extended reality would be a very powerful tool to help kind of, you know, fire up some of those neurons differently because there's tactile memory involved if they're doing it in a very simulated environment.
Speaker 3 There's been a lot of military studies about that type of work with simulated environments, which is why I think that idea of bringing it further out into
Speaker 3 astrophysics research and communications and all that is such a great idea. So yeah, it's a great question.
Speaker 2 So do you think they learned anything from Pokemon Go? Oh,
Speaker 2 they insert virtual reality creatures out there? Yeah.
Speaker 3 Yeah, I honestly think Pokemon Go is a great tool. Like that was such a brilliant XR application that people picked up on such a massive scale.
Speaker 3 And I think having that kind of learning opportunity for different scientific and engineering activities would be fantastic.
Speaker 3 I mean, I'm not saying aliens, but like, you know, different kinds of experiences would be great.
Speaker 2 It got people off the couch.
Speaker 3 It did. It did.
Speaker 2 It got them walking around the neighborhood.
Speaker 2 It clearly did something good because people were out.
Speaker 2 And it created a whole community of people because people would meet up to find the characters and meet one another like, oh man, you're a total nerd too.
Speaker 2 My God,
Speaker 2 I thought I was alone.
Speaker 3 I love that.
Speaker 2
So great. Super cool.
All right.
Speaker 2 This is Alan Keeser who says, suppose
Speaker 2 you get
Speaker 2 one perfectly synchronized week on Chandra, James Webb,
Speaker 2
and an event horizon style array. Yeah.
Okay. Okay.
Speaker 2 What single measurement would you make to decisively test how black hole feedback regulates galaxy growth.
Speaker 2 And what exact observable or statistic would you publish so the rest of us can tell if you're right? Alan from Santa Barbara
Speaker 2 and he says, P.S. I am another show off.
Speaker 3 Yes, is that a question? That's amazing. First of all, again, I feel like you might already know the answer to that question.
Speaker 2
Yeah, I got a feeling Alan knows the answer to a lot of questions. Alan's sitting up in his classroom just like, these kids are stupid.
Let me ask Neil,
Speaker 2 Kim,
Speaker 2 these dumbasses I'm teaching all day long.
Speaker 3 Yeah, yeah, I feel like I'm trying to re-stump in that one, which is totally fine.
Speaker 3 You know, first of all, I would have to say it has to be a large community collaborative thing. There would be no magic wand to give me any of those superpowers with my super friends.
Speaker 3 By the way, the listing of Chandra and Webb and EHT together, like that is a very cool group, I think, to be a part of. So major props to that.
Speaker 3 But all of these types of scientific observations with these massive telescopes is truly highly collaborative and all very peer-reviewed. So no one person is ever making that kind of decision.
Speaker 3 I feel like I'm being a bit of a party pooper there. But I would say with the type of object I would pick is probably Centaurus cluster or a similar type
Speaker 3 of
Speaker 3
galaxy cluster with a nice active supermassive black hole at the center. Chander could map the black hole activity.
Chander could map the surrounding
Speaker 3 environment of the black hole, the x-ray cavities kind of carving out into the gas by those black hole jets.
Speaker 3 Webb could definitely provide the sort of map and history timeline of the star's evolution throughout that area as well. That would give you some really great constraining information.
Speaker 3 And then the Event Horizon Telescope, which is another amazing telescope and has already taken some incredible incredible images, would hopefully be able to get us that
Speaker 3 jet launch point, I would say, from the black hole. That would be really cool.
Speaker 3 So being able to figure out, like, you know, what I love about supermassive black holes is that they're responsible for the care and feeding of the galaxy. And I love that.
Speaker 3 Alan's question, I believe, is kind of getting at that point, like, how can we get even more data about it? So that would be my suggestion.
Speaker 2 And if I say something just about my people,
Speaker 2 my community of astrophysicists, unlike the example that Kim is describing, because that's just, you want to collaborate with people who would be on the various telescopes with a peer-reviewed project.
Speaker 2 However, if something goes down in the sky that no one saw coming
Speaker 2 and I discover it first
Speaker 2 and I see it first, I can set out a notice
Speaker 2 that night.
Speaker 2 for any telescope where they can peel off an hour of their observing program to get data because each telescope is going to be different, a different
Speaker 2 focus, different
Speaker 2 bandwidth, different
Speaker 2
and if the object sets for me, it's rising for somebody else in the world. Right.
And so we, my community is very supportive when there's a
Speaker 2 phenomenon that comes and goes and you got to get it in the spot. Collegiate.
Speaker 2 Collegiate telescopes. Yes.
Speaker 3 Tendera does that all the time.
Speaker 2 That's exactly.
Speaker 2 We have a code red.
Speaker 2 That's exactly
Speaker 2
how that would play out. So that can happen for events that occur in the sky.
But something so organized as the black hole in the middle of a galaxy trying to get the best data,
Speaker 2 like Kim said, that's a peer-reviewed, pre-organized activity. Cool.
Speaker 2 So, Kim, your Chandra deep field, is that a deep field unto itself? Or did it do the same, quote, deep field that Hubble obtained?
Speaker 3 So Chandra did its own deep field, the Chandra Deep Field South, but it also did coordinated campaigns with
Speaker 3 Goods Deep Field that both Hubble and Chandra have looked at. And there have been additional campaigns as well.
Speaker 3 So deep fields are an area of really rich research for Chandra and Hubble and other telescopes. And you kind of can't have enough of them.
Speaker 2 Yeah, you know how the first deep field was obtained?
Speaker 2
No. The head of the Hubble Institute.
And now I just remember.
Speaker 2 With his discretionary time, because every director gets a little bit of time but he can do whatever the hell they want right and he said find me an emptiest area of the sky you can he was flexing hard let's play play and creativity at work yes and he said let's burn some telescope time
Speaker 2 looking at nothing looking at nothing and and then something was there and he was the luckiest director
Speaker 2 because if nothing was there
Speaker 2 he would have been in trouble you know he would not have been the director the next day
Speaker 3 yes But it was the same for Chandra. Like, because Chandra has less time to kind of give, right? It has to look at objects longer than Hubble has to, it was still a risky proposition.
Speaker 3 But they looked at this one spot, the Chandra Deep Field South, which was seemingly empty, and they looked at it for like 40 days and 40 nights.
Speaker 3 And they found this massive population of thousands of black holes and galaxies with black holes at their core. So it's lovely when you can be creative.
Speaker 2 Let me ask you both this:
Speaker 2 whether there's empirical evidence or just your opinion,
Speaker 2 is there anywhere we can point a lens and not see something in the universe?
Speaker 3 With our current telescopes?
Speaker 2
In your opinion. Because I know we haven't looked at every place.
So in your opinion, is there any place we can point a lens and not see something?
Speaker 2 Up your ass.
Speaker 2 No.
Speaker 2 No,
Speaker 2 no, no. I gotta go.
Speaker 2 Because we're not gonna keep that in the show.
Speaker 2 and I gotta go because if we don't keep that in the show
Speaker 2 there's no reason for me to exist I have no reason to exist
Speaker 2 if we don't keep that in the show I have no reason to exist like that's you can't get better than that so I'll lead off and then Kim will follow up on that so
Speaker 2 I think that a better way to say that is
Speaker 2 if you have a telescope that has opened a new window to the universe in whatever way in the time
Speaker 2 in timestamps, in
Speaker 2 wavelength,
Speaker 2 in how big it is.
Speaker 2 If it's a telescope that did not previously exist and you put it anywhere, it's going to make a discovery because it's looking at the universe beyond
Speaker 2 the fence that was set up by everything else you've been using to look at the universe.
Speaker 2 Now,
Speaker 2
but the universe is so vast. Kim, I don't think there's a place where there's nothing happening.
What do you think?
Speaker 3 Oh, I agree. I mean, like what Hubble did for the optical field, what Chander has done for the X-ray field, what Webb has done for the infrared field so far.
Speaker 3 Like each time we launch these new telescopes, we're finding those things deeper, earlier, back further in space and time.
Speaker 3 And so it really is, I think, mostly at this point a limit of our technological achievements.
Speaker 3 I don't know.
Speaker 3
That's a great question. It's a very exciting thing to think about.
Props to you.
Speaker 2 Props to you.
Speaker 2
Well, thank you. Thank you.
I'm going to say that the original answer was better than my question.
Speaker 2 And I think I don't even, I think, fully pronounce the words in that comment. Okay, good.
Speaker 2 Good, good.
Speaker 2 So, Kim, I think we got to call it quits there, but you've got a book coming out.
Speaker 2 Tell me the name of that book, How to Freak Out Your Kids. What is it? Sorry.
Speaker 3 Yeah, no, I hope not. MySpace Will Freak You Out is coming out in February.
Speaker 2
I'm excited. And it's a hand-picked assortment of really freaky things in the universe.
And
Speaker 2 think about it, that's a long overdue book.
Speaker 2 It's a lot of fun. I think it's fun.
Speaker 3 Like Lemony Snicket for Space.
Speaker 2
Nice analogy. That's great.
Yeah, the series of unfortunate events. Is that what that was?
Speaker 3 Yes, yes. I love that.
Speaker 2
So, and that's your ninth book. So congratulations on staying with it.
We're in the same biz.
Speaker 3 Not quite. I try.
Speaker 2 Not quite the same biz as you, but I try.
Speaker 2 So, Kim, this has been a delight.
Speaker 3
Thank you. It has been so fun.
As always,
Speaker 3 I'm still waiting for my jacket.
Speaker 2 Oh,
Speaker 2
she's starters. Yeah.
And
Speaker 2
I said master's gold jacket, but the master's jacket is green. It's great.
The hall of fame is gold. Oh, right.
And that's what you would get.
Speaker 3 I think the gold sounds nice.
Speaker 2
We'll work on that, Kim. Yeah.
All right. So good luck with this effort.
And sometimes that helps too, I'm told.
Speaker 2 But you're at it and you're at it strong. And we'd be delighted for this to have been your fifth appearance on Star Talk.
Speaker 2 For anyone who wants to catch our prior episodes with her, just check our archives. We have a vibrant archives of past episodes.
Speaker 2
You can search by name, by guest, by topic, and it's all there for you in case you're a new joiner for who and what we are. All right.
Chuck, always good to have you. Always a pleasure.
Speaker 2 And Kim, we all love you. Stay strong.
Speaker 3 Thank you. It's so nice to be here.
Speaker 2 This has been Star Talk Cosmic Queries, the Kim Arkand edition. How you like that?
Speaker 2 As always, I bid you to keep looking up.
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