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What we can learn from galaxies far, far away

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    Here are some images of clusters of galaxies.
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    They're exactly what they sound like.
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    They are these huge collections of galaxies,
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    bound together by their mutual gravity.
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    So most of the points that you see on the screen
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    are not individual stars,
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    but collections of stars, or galaxies.
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    Now, by showing you some of these images,
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    I hope that you will quickly see that
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    galaxy clusters are these beautiful objects,
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    but more than that,
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    I think galaxy clusters are mysterious,
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    they are surprising,
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    and they're useful.
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    Useful as the universe's most massive laboratories.
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    And as laboratories, to describe galaxy clusters
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    is to describe the experiments
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    that you can do with them.
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    And I think there are four major types,
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    and the first type that I want to describe
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    is probing the very big.
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    So, how big?
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    Well, here is an image of a particular galaxy cluster.
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    It is so massive that the light passing through it
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    is being bent, it's being distorted
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    by the extreme gravity of this cluster.
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    And, in fact, if you look very carefully
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    you'll be able to see rings around this cluster.
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    Now, to give you a number,
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    this particular galaxy cluster
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    has a mass of over one million billion suns.
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    It's just mind-boggling how
    massive these systems can get.
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    But more than their mass,
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    they have this additional feature.
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    They are essentially isolated systems,
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    so if we like, we can think of them
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    as a scaled-down version of the entire universe.
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    And many of the questions that we might have
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    about the universe at large scales,
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    such as, how does gravity work?
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    might be answered by studying these systems.
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    So that was very big.
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    The second things is very hot.
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    Okay, if I take an image of a galaxy cluster,
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    and I subtract away all of the starlight,
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    what I'm left with is this big, blue blob.
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    This is in false color.
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    It's actually X-ray light that we're seeing.
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    And the question is, if it's not galaxies,
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    what is emitting this light?
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    The answer is hot gas,
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    million-degree gas --
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    in fact, it's plasma.
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    And the reason why it's so hot
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    goes back to the previous slide.
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    The extreme gravity of these systems
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    is accelerating particles of gas to great speeds,
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    and great speeds means great temperatures.
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    So this is the main idea,
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    but science is a rough draft.
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    There are many basic properties about this plasma
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    that still confuse us,
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    still puzzle us,
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    and still push our understanding
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    of the physics of the very hot.
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    Third thing: probing the very small.
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    Now, to explain this, I need to tell you
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    a very disturbing fact.
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    Most of the universe's matter
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    is not made up of atoms.
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    You were lied to.
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    Most of it is made up of something
    very, very mysterious,
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    which we call dark matter.
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    Dark matter is something that
    doesn't like to interact very much,
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    except through gravity,
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    and of course we would like to learn more about it.
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    If you're a particle physicist,
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    you want to know what happens
    when we smash things together.
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    And dark matter is no exception.
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    Well, how do we do this?
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    To answer that question,
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    I'm going to have to ask another one,
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    which is, what happens when galaxy clusters collide?
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    Here is an image.
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    Since galaxy clusters are representative
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    slices of the universe, scaled-down versions.
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    They are mostly made up of dark matter,
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    and that's what you see in this bluish purple.
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    The red represents the hot gas,
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    and, of course, you can see many galaxies.
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    What's happened is a particle accelerator
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    at a huge, huge scale.
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    And this is very important,
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    because what it means is that very, very small
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    effects that might be difficult to detect in the lab,
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    might be compounded and compounded
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    into something that we could
    possibly observe in nature.
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    So, it's very funny.
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    The reason why galaxy clusters
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    can teach us about dark matter,
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    the reason why galaxy clusters
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    can teach us about the physics of the very small,
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    is precisely because they are so very big.
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    Fourth thing: the physics of the very strange.
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    Certainly what I've said so far is crazy.
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    Okay, if there's anything stranger
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    I think it has to be dark energy.
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    If I throw a ball into the air,
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    I expect it to go up.
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    What I don't expect is that it go up
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    at an ever-increasing rate.
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    Similarly, cosmologists understand why
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    the universe is expanding.
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    They don't understand why it's expanding
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    at an ever-increasing rate.
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    They give the cause of this
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    accelerated expansion a name,
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    and they call it dark energy.
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    And, again, we want to learn more about it.
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    So, one particular question that we have is,
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    how does dark energy affect the universe
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    at the largest scales?
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    Depending on how strong it is,
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    maybe structure forms faster or slower.
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    Well, the problem with the large-scale structure
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    of the universe is that it's horribly complicated.
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    Here is a computer simulation.
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    And we need a way to simplify it.
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    Well, I like to think about this using an analogy.
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    If I want to understand the sinking of the Titanic,
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    the most important thing to do
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    is not to model the little positions
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    of every single little piece of the boat that broke off.
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    The most important thing to do is
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    to track the two biggest parts.
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    Similarly, I can learn a lot about the universe
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    at the largest scales
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    by tracking its biggest pieces
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    and those biggest pieces are clusters of galaxies.
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    So, as I come to a close,
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    you might feel slightly cheated.
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    I mean, I began by talking about
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    how galaxy clusters are useful,
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    and I've given some reasons,
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    but what is their use really?
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    Well, to answer this,
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    I want to give you a quote by Henry Ford
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    when he was asked about cars.
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    He had this to say:
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    "If I had asked people what they wanted,
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    they would have said faster horses."
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    Today, we as a society are faced
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    with many, many difficult problems.
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    And the solutions to these
    problems are not obvious.
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    They are not faster horses.
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    They will require an enormous amount of
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    scientific ingenuity.
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    So, yes, we need to focus,
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    yes, we need to concentrate,
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    but we also need to remember that
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    innovation, ingenuity, inspiration --
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    these things come
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    when we broaden our field of vision
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    when we step back
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    when we zoom out.
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    And I can't think of a better way to do this than
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    by studying the universe around us. Thanks.
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    (Applause)
Title:
What we can learn from galaxies far, far away
Speaker:
Henry Lin
Description:

In a fun, exciting talk, teenager Henry Lin looks at something unexpected in the sky: distant galaxy clusters. By studying the properties of the universe's largest pieces, says the Intel Science Fair award winner, we can learn quite a lot about scientific mysteries in our own world and galaxy.

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Video Language:
English
Team:
closed TED
Project:
TEDTalks
Duration:
06:43

English subtitles

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