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  • This is the golden eye of the James Webb Space TelescopeUnparalleled in scope and scale,

  • Webb is the largest telescope to ever launch into space. It's a little bit like our generation's

  • Apollo in that it was very challenging to build but the payoff is also very large. This

  • is about as powerful as it gets. This is an extremely ambitious project. We developed

  • all these new technologies that didn't even exist, but we needed it to carry out the science.

  • An international project like this that has countless firsts takes time, but the

  • painstaking effort to design, construct and test Webb’s optical system will be worth

  • the wait. Overnight, the eye of the telescope will revolutionize our understanding of the

  • cosmos and be set loose on the biggest questions in astronomy.

  • I've been working on the James Webb Space Telescope for 20 years.

  • When I first started, we really didn't even know

  • exactly what the design would look like, what materials we would make the mirrors out of,

  • how many segments the telescope would be. We actually had to invent multiple technologies.

  • That's because the astronomical community was after something that hadn’t been observed before

  • the early universe. The first stars and galaxies started to form 100 to 250 million years after

  • the Big Bang, around 13.6 billion years ago. Because the universe is expanding,

  • the visible light from the early universe gets stretched into the infrared and that's called a cosmological

  • redshift. It's this cosmological redshift that Webb's optics will be hunting for, to

  • uncover the story of the early universe. Infrared light can pass through dust in the universe.

  • And so it allows us to peer through dust clouds and see, for example, stellar nurseries

  • No other telescope today has the collecting power and sensitivity that NASA’s JWST has to

  • lift the veil on the universe’s secrets. The James Webb Space telescope is sensitive

  • enough that if there were a bumblebee at the distance of the moon, we would be able to

  • detect it. The telescope’s core superpowers come from its advanced optical system. James

  • Webb’s eye, otherwise known as the Optical Telescope Element, consists of four ultra

  • reflective golden mirrors and dozens of subsystems to support the massive optics. The first thing

  • you recognize is the gold mirrors. There's a reason why we chose gold is because

  • it has a very high reflectivity in the infrared. Out of the four mirrors, it’s the primary

  • one that really stands outThat's the first mirror that light hits. And in this case we

  • have 18 segments that are hexagonal shaped. Which means each mirror actually acts as a

  • separate telescope until theyre aligned in space to work as oneAll of the 18 hexagonal

  • segments and additional mirrors are made of beryllium, a strong and lightweight metal

  • that holds its shape at cryogenic temperatures. Remember, space is a balmy -270° C. The other

  • subtlety of it all is because it's infrared, the mirrors have to be cooled to very cold

  • temperatures so that they don't produce heat in the form of infrared light that would contaminate

  • the images. And lastly, a large telescope gives you resolution. The resolution goes

  • with the diameter of the primary mirror. Webb’s primary mirror is 6.5 meters in diameter,

  • which gives the telescope more than 6 times the collecting area of the Hubble Space Telescope!

  • It's a lot like collecting raindrops and the bigger the bucket, the more raindrops you

  • collect. And when you're trying to see the very early universe, which is very dim, you

  • need to collect a lot of photons. For the engineering team, it’s easier to look back

  • at what was achieved when youre at the finish line. So many aspects of the telescope

  • needed to be invented before manufacturing began years ago, from the segmented beryllium

  • mirrors to the large sunshield for keeping the system cold, to algorithmslots and

  • lots of brand new algorithms for keeping the mirrors aligned 1.5 million kilometers away.

  • In terms of a science mission like this, this is the largest, most ambitious one that NASA

  • has ever taken on. And it's arguably one of the most complicated, but also powerful ones.

  • That’s because to see the universe like never before, it requires a new type of observatory.

  • For the JWST team, building that observatory meant constructing a complex cascade of mirrors

  • that can focus light down like no other telescope before it. The first mirror is the primary mirror.

  • That's what initially collects the light from the distant universe,

  • the light then converges down to a secondary mirror

  • and the secondary mirror continues to focus the light and then that reflects light to

  • what we call the tertiary mirror. And then finally, the light is sent to a fourth mirror,

  • which is the fine steering mirrorAnd the purpose of that mirror really is to correct

  • slow drifts between the telescope and the spacecraft. After all that, an image is created

  • as the light enters the four science instrumentsWe call them science instruments, but you can

  • think of them as cameras. They each have their own detector which actually collects the light,

  • like the detector on your camera. The light photons get converted into electrons.

  • They get recorded onto a data recorder on the telescope. And then the data actually

  • gets sent back down to the earth using the deep space network. And once we have the first

  • completed images, the long wait... will have ended. So space telescopes are like time machines

  • in a sense. They can take us back and collect these photons that were created at the very

  • beginning of the universe. That light is always there. It's always coming down, we just haven't

  • had the capability. Until nowIn the first year of operations, Webb’s mirrors will

  • collect light from early galaxies and stars, the environment around black holes, supernovae,

  • and other space phenomena with greater sensitivity than ever before. And of all the highly anticipated

  • observations one is a personal favorite for Michael. I'm really excited about the exoplanet

  • discoveries. We know of over 4,000 exoplanets orbiting other stars. But we don't really

  • have an understanding of what their compositions are. And that's one of the key aspects of

  • the Webb mission. For the first time, we'll really get a good understanding of their properties,

  • and those are very fundamental features for understanding how they formed, how

  • they evolved and also will give us some insight as to the habitability of these exoplanets,

  • whether there might be liquid water where life could exist. By searching for the building

  • blocks of life elsewhere, it can give us insight into how life began on our own pale blue dot.

  • Webb’s science mission touches on so many fundamental questions in cosmology that it

  • holds the promise of rewriting and expanding our textbooks for years to come. Every time

  • we have a transformative increase in observing capability like Webb, there's just tremendous

  • scientific discovery. We used to use the phrase early when we were developing Hubble, expect

  • the unexpected. And I think here, you can almost say, expect the unexpected squared.

  • The James Webb Space Telescope is a new kind of telescope, it's never been done before.

  • This is really new terrain for NASA and for the world. And setting a stage for future

  • telescopes that are scalable to larger sizes. Which means if we ever want to see

  • a pale blue dot around another star, the foundation has been set

This is the golden eye of the James Webb Space TelescopeUnparalleled in scope and scale,

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How The Golden Eye Of The James Webb Space Telescope Will See The Edge Of The Universe

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    Summer に公開 2021 年 11 月 27 日
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