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  • Hubble will die one day.

  • Obviously Hubble the person is already dead, but the Hubble telescope will die one day.

  • And we have to both be mentally and astronomically prepared.

  • Something will wear out on Hubble space telescope basically.

  • Either calibration lamps or ...

  • ...some of the fuel to change which direction it's pointing in, it will eventually stop working.

  • We will no longer be able to get images from Hubble.

  • [Sunrise over the Hubble space telescope...

  • ...illuminating the golden solar arrays, those arrays to be retracted for the final time a few hours from now.]

  • Nasa, ESA, as a new space telescope, have got a new Hubble in the pipeline.

  • It's called James Webb Space Telescope and...

  • ...this is what it looks like. It's infrared not optical, unlike Hubble so it's not really a true follow-up...

  • ...because Hubble looks in the UV and the optical and an infrared, whereas James Webb will look out the very far...

  • ...infrared. James Webb will be at the Lagrange 2 point, so I know that Sixty Symbols is done a...

  • ...Lagrangian video before but basically a Lagrange point is a stable point in a two-body system.

  • So we have the sun and we have the Earth...

  • ...going around the sun and basically there are five points in those orbits at which, if you put something...

  • ...it wouldn't move relative to the Earth and Sun.

  • So it would stay where it was. So L2 is sort of beyond Earth, away from the Sun. And basically it will have a...

  • ...365-day year, the same as the Earth, but it will be orbiting further around. It will be...

  • ...launched in an Ariane 5, which is a really really successful ESA Rocket.

  • [Allumage EAP, décollage]

  • And then they're gonna give it a little bust. And then they'll get it enough energy to get to L2...

  • ...but really really slowly. So what they'll do is...

  • ...is kind of like going up a hill, if you will. So they'll give it enough energy to boost it up the hill...

  • ...but so much so it will slow down, slow down, slow down,...until it reaches the very top, at which point it will stop.

  • Just like it was a really good putt?

  • Yeah! Like a really, really good putt, yeah.

  • And it'll just sort of stop at the edge and then just fall in.

  • In that time, the antenna will fold out, so it can talk to Earth. And then the whole thing moves upwards as well...

  • ...and it's called a spacecraft "bus", they call it.

  • The whole thing will move up and make room for all of the equipment down below.

  • The sun shield will all fold out as well.

  • This is this huge tennis-court sized, five-layer, intricate sun shield.

  • This, which we call the secondary mirror, ...

  • ...so as light comes in here, bounces off here, bounces onto the secondary and then...

  • ...into the center, where it's detected. That will also be up here during launch and will get folded down to the right position.

  • The mirror itself, so this segmented array, ...

  • ...will also fold out from being folded up inside the rocket.

  • So what they've had to do is they had to design the shape of the mirror...

  • ...so that it is the wrong shape at room temperature...

  • ...but by the time that it gets to, like, the vacuum of space it will cool and warp to the right shape.

  • It feels like they've made this too complicated, like they seem, like, they've been too ambitious. Am I wrong?

  • I get that feeling as well, but I think it's because I...

  • ...I'm not an engineer, a space scientist engineer, so I can't...

  • ...comprehend what is too complicated, you know. Let's leave it for the rocket scientists to tell us...

  • ...you know, what's too complicated. They have such belief that this will work.

  • So the astronomical community, you know, has faith in them and says...

  • "OK, well, this is what I want to do with it". There's...

  • ...a huge long list of things that could go wrong. It could...

  • ...just blow up being... trying to be launched.

  • The antenna couldn't even fold out. The sun shields might not deploy properly.

  • The mirror might not fold out properly, the secondary mirror might not fold out properly, the whole thing might not move up, it might jam.

  • Like, the cryostat, to cool everything, might not come on.

  • The electronics might be fried, it might get shook up too much than it might not work.

  • I mean, it's kind of terrifying trying to list everything that might go wrong, but also exciting.

  • Because they've had to...

  • ...think about "how can we stop that from happening?"

  • There's about 10...

  • ...brand new technologies that've gone into the JWST that haven't been tested before.

  • Everything's already built. You know, everything's being tested repeatedly...

  • ...at NASA Goddard, which is in the Washington DC area.

  • They're vibration testing, they are testing the solar shields, how they pull out.

  • Someone said to me that, the test they've seen, it happened through the day, but it took two weeks for the solar shields to fully...

  • ...open up, they said it was like watching paint dry. Okay, you'd go for lunch, come back, and they were like they haven't moved at all.

  • It's going, undergoing, so much rigorous testing to make sure that everything can stand up to the launch and...

  • ...fold out in the, y'know, the sort of situation that it needs to.

  • Hubble was optical and UV. It had...

  • ...stuff that it could specifically do. But it's limited. It can only see so far, and that's because, obviously...

  • ...if you imagine stars and galaxies are always giving us optical light, ...

  • ...the further away they are the more that light is redshifted and so Hubble can't actually see the very distant galaxies.

  • Because there's nothing really in the optical...

  • ...wavelengths that it can see anymore.

  • So we have to look in the infrared.

  • I've printed out these to show you... So this is...

  • ...the optical image of the Eagle Nebula, taken by Hubble. It is my favorite Hubble image, it is beautiful.

  • It's of a star forming region in the Milky Way. You can see all the dust clouds. It's absolutely beautiful.

  • On your...right?... yeah, OK...

  • ...is the infrared image from Hubble as well.

  • And although the optical one is more sort of visually spectacular...

  • ...the infrared one is more scientifically spectacular...

  • ...because you can see through all the dust and the gas that's in this nebula, and so you can...

  • ...learn more from the infrared image than you can from the optical.

  • Obviously, to get enough light from an object you have to stare at it incessantly and...

  • ...the idea with James Webb is that it's got such a big mirror...

  • ...(6.5m, as opposed to, you know, Hubble's 2.4)...

  • ...that you don't have to stare for very long at all. So that, uh... one of the...

  • ...quotes I remember was that if you took the Spitzer Space Telescope, which is...

  • ...infrared as well... it did an entire survey of...

  • ...galaxies, and it took something like 550 hours of observing time...

  • ...that's just actually staring at the sky, that's not including all the time it takes to repoint the telescope.

  • If you end up doing the exact same survey again with James Webb, it would take 30 minutes!

  • The other thing it's gonna be able to do...

  • ...or people hope it will be able to do, is to detect the first signs of life in our universe...

  • ...y'know, beyond our own planet, obviously.

  • I mean, I'm not talking about sort of you know contacting ET or little green men here.

  • What I'm talking about is...

  • ...biosignatures.

  • Y'know, this is the idea that you will be able to detect in that atmosphere, say, water or oxygen or...

  • ...carbon dioxide.

  • Something that, we know, on Earth...

  • ...is a signature that life is here.

  • The way that they've detected exoplanets in the past is to have...

  • ...the exoplanet's star here... if you're sort of the Kepler Spacecraft, which is the one that's been detecting exoplanets...

  • ...and I am the star... then what happens is, you're observing light from me, and you're like "Yep...

  • ...there's a star there, there's definitely a star there". And then a planet moves across...

  • ...my face and basically it will produce a tiny little dip...

  • ....in my brightness.

  • In which case you'd be like "Oh! A planet there!"

  • What they do now is they'll wait for it to transit...

  • ...and they'll wait for the the light from the star to pass through a teeny tiny bit of the atmosphere of that planet...

  • ...and then they will take that light and split it into its rainbow, into its spectra.

  • They'll take off the light from the star and they'll be left with the absorption spectra of the atmosphere of that planet.

  • Even if we were very confident that we had detected signs of life in an atmosphere...

  • ...and we said "OK, this is definitely, sort of, like Earth"... the most Earth-like we could possibly ever find.

  • Say it's a star exactly like the sun, and it's at Earth's size and at Earth's, y'know, radius planet and everything...

  • ...and it's got ozone, and it's got hydrogene, it's got CO2, everything...

  • ...it might be 10,000 light years away.

  • And if we were ever gonna have a conversation with these people...

  • ... I call them people... with this life...

  • ...if they were intelligent life...

  • ...it would take us 10.000 years to send a signal and for them to receive it, and 10.000 years to come back.

  • So it would be a 20-thousand-year wait for the other side of the conversation.

  • In the paper, there's, you know, the most Earth-like planet every six months.

  • And that'd be the most Earth-like from its mass or from its radius or from the distance it orbits around its star...

  • I that'll be the most earth-like from its mass or from its radius or from the distance it orbits around its star or the fact

  • ...or for the fact that the star is the same as the sun.

  • We've never really found one that fits all of those...

  • ...criteria at once. It's pretty scary because it won't launch till October 2018...

  • ...but they already have science proposals in. If you want to do something very specific...

  • ...that's your science, the call for proposals is November, this year!

  • So everybody is already starting to think...

  • "What will I do? How will I observe this? How long will it take me?"...

  • ...'cause you have to put all that in the proposal before someone decides "Yes or no, you don't get time"...

  • ...before it's even launched.

  • Before it's even gone to the launch site, like, it won't even be in French Guiana before people put in...

  • ...telescope proposals.

  • I bet those people are going to be nervous when they'll launch it, too?

  • Yes! Definitely! If your, sort of, scientific career future prospects of...

  • ...you know, depend on you getting the James Webb Space Telescope time, ...

  • ...you need that thing to work.

  • ...portion of the spectrum.

  • We feel right now that there's probably no real science that we can do with the wide-field camera at this time.

  • And I'll stop there.

  • The thing about Hubble is that it was launched into low Earth orbit and...

  • ...it was always intended that it would be visited by astronauts. And so a few years later one of five...

Hubble will die one day.

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ジェームズ・ウェッブ宇宙望遠鏡 - 60のシンボル (James Webb Space Telescope - Sixty Symbols)

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    林宜悉 に公開 2021 年 01 月 14 日
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