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[ INTENSE MUSIC ]

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-We have lock, and are good to send that command.
We have thirty-one minutes and thirty-two

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seconds for our support.

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Go for status buffer dump.

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-What you're looking at with a telescope, of
course, is the light from billions of light-years

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away. So the further you look, the more
you're going back towards the Big Bang and

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understanding how the universe was formed.

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-The Webb telescope will be groundbreaking
because it has capabilities that are different

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than the Hubble Space Telescope.

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-We have equipment that is so much more powerful
than anything we've ever had before, that

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it's almost impossible to tell
what we will discover.

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Hubble Eye In The Sky

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Episode 3: Time Machines

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-Hubble's accomplishments include something

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called the deep fields.

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Looking out into space and collecting
light, sometimes for many days,

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these deep fields have revealed visually to us,

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a universe absolutely teaming with galaxies,
hundreds of billions of galaxies.

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-One of the neat things about the Ultra Deep Field,

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and one of the things that made it so unique,

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was how long it took us

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to take that image.
There's an exposure time that's expressed,

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I think it's 11.2 days. It’s a very, very
long exposure time, but probably what's more

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important is how many orbits it took us to
do that. 400 orbits of Hubble data to take

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that image. You only get
15 orbits a day. To take 400

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orbits and say we're going to observe this
one spot in the sky for 400 orbits, and the

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really unique thing about that was they picked
a spot where there wasn't anything. They looked

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and they said there's absolutely nothing here.
And they said, you want to spend 400 Hubble

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orbits looking at nothing? And they said yes,
because we want to see what it can see. And

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I think the results from the science, I mean
it was amazing. What they saw was spectacular.

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-Hubble had spent two weeks taking pictures of empty places

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in the sky. And they saw they weren't empty at all

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there were thousands and thousands of galaxies.

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-We were amazed how many galaxies we found,

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and we continued to go back to that

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portion of the sky to increase that visibility.

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-The Hubble Space Telescope is an outstanding
time machine.

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It's incredibly important for our studies
with the Hubble Space Telescope to realize

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that when we're looking at a galaxy, we're
seeing it as it was millions of years ago,

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sometimes billions of years ago. It's taken that
long for the light to get to us.

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-What you're looking at with a telescope, of course,

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is the light from billions of light-years away.

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So the further you look, the more you're going back towards

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the Big Bang and understanding how the universe was formed.

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-What Hubble has revealed is that the universe
has in fact changed over these billions of

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years of time. The early galaxies, the very
distant ones as we see them, are simple. Sometimes

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they're messy looking, they're small. They
haven't had time yet to form that grand

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spiral structure.
Over time, we see galaxies actually merging

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with other galaxies and growing bigger and
bigger, and those mergers can look like train

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wrecks in our Hubble images.

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-These very, very deep exposures that Hubble
has been able to take, we have seen right to

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the edge of the universe, thirteen and a half billion years.

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When Hubble was first designed and envisioned,
it was never thought it could actually see

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that far out. But because of the advances
in the instruments that we've been able to

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put up on the telescope, and also the cleverness
of the scientists, they've come up with very

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interesting observing scenarios, doing these
really deep exposures, where we just sit there

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for orbit after orbit, after orbit gathering
the photons, we’ve been able to push Hubble

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out very, very far.

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-As Hubble looks out into these fields of galaxies,
we sometimes see clusters of galaxies. These

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are galaxies that are held nearby each other
by their mutual gravity.

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These clusters are massive conglomerations.
There's so much mass that they have an actual

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observable impact on space-time itself.
Einstein predicted that mass distorts space,

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but we didn't realize we could actually see
the effects of that. But with Hubble, we have

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been able to see distortions in space around
clusters of galaxies. The way we see that

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is when light from a background galaxy travels
through that cluster of galaxies, or around

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it, due to this gravitational lensing effect.
The lensing also magnifies that background

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galaxy, so if we look in some of these distorted
arcs, we can see more detail than we would

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ever have been able to see without gravitational
lensing, nature’s boost.

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-There are observations where we're explicitly
looking for the lensing and

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we're getting science out of that just otherwise

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would just not be doable. Hubble has really taken that

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to a next level. It's doing large amounts

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of astrophysics that it's just never been able to do before.

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-Some of what we're doing with Hubble is to
prepare for the new James Webb telescope,

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which we anticipate launching in 2021, which
will be able to see farther into the infrared

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part of the electromagnetic spectrum. That
enables us to see some galaxies that are difficult

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for Hubble to see because they're so far away
that their light is traveling through us through

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expanding space and gets stretched out into
redder wavelengths, often far into the infrared

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part of the spectrum. Even sometimes beyond
what Hubble is able to detect well. The Webb

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telescope will give us more information about
some of those very distant galaxies.

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-The James Webb Space Telescope is the follow-on
telescope after the great Hubble telescope.

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It extends the discoveries of Hubble into
the infrared spectrum region.

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We think that the first objects that grew
out of the Big Bang material probably happened

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in about a hundred million years after the
start. And we think the Webb telescope can

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pick them up. They're rare, they're hard to
find, but they should be there.

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The farthest we've been able to see with
the Hubble telescope goes back about 600 - 800

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million years after the expansion began, so
we think we get much, much closer to the

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first objects with the Webb telescope.

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-Hubble gives information that the Webb telescope
cannot give about

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visible and ultraviolet emission from things in the universe,

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and when we have all of that information coming in

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at the same time, it's like a banquet
of scientific return.

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-Now when we get the complete picture of every
wavelength you can possibly see from ultraviolet

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to infrared, we hope to have
the story of the growth

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of the first galaxies from the primordial material.

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So that will be a huge accomplishment
that depends on both pieces

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of equipment, the Hubble telescope and the
James Webb telescope working together.

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-So, astronomers are very excited about this
probability that we'll have both the Hubble

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Space Telescope and the Webb telescope operating
at the same time for quite a few years. That

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will give us an abundance of new understanding
about the universe.

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And already right now with Hubble, we're doing
preparatory observations for the Webb telescope.

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We're using Hubble to do things, for example,
like surveying distant galaxies to find out

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which ones would be prime targets for the
Webb telescope.

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In fact, scientists around the world are proposing
observations with Hubble right now specifically

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to help us learn information that will be
useful for making the best use of the Webb

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telescope as soon as it's launched and gets
going in its science observations.

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-I think the Hubble telescope has been the
most productive science instrument ever built.

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In astronomy, there's what we knew before
Hubble, and now, there's what we know after

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Hubble. They're so different.

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Of course, Hubble has now had a life of 30
years, so it's had a long time to make this

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revolution happen. So it's not all at once.
It's a gradual revolution, but it's still

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a huge revolution.

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Knowledge has changed dramatically over the
30 years of life of the Hubble telescope.

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so you couldn't even have imagined when the
Hubble was launched that we would have the

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wonderful cameras and spectrometers that we
fly today.

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We figured out how to send astronauts, we
trained the astronauts, we figured out what

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instruments could be put in. We figured out
how to repair everything that went wrong on

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the Hubble, and it's still alive today, 30
years after launch.

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I am so thrilled to say that our people were
able to do that.

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That's the operations team that makes this
possible. It's a miracle as far as I'm concerned,

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because it didn't have to be that way, but
they made it happen.

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Hubble Eye In The Sky


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[ INTENSE MUSIC ]