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Do you ever think
about what would happen
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if the world were a little bit different?
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How your life would be different
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if you were born 5,000 years from now
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instead of today?
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How history would be different
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if the continents
were at different latitudes
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or how life in the Solar system
would have developed
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if the Sun were 10 percent larger.
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Well, playing with these
kinds of possibilities
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is what I get to do for a living
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but with the entire universe.
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I make model universes in a computer.
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Digital universes that have
different starting points
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and are made of different amounts
of different kinds of material.
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And then I compare
these universes to our own
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to see what it is made of
and how it evolved.
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This process of testing models
with measurements of the sky
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has taught us a huge amount
about our universe so far.
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One of the strangest
things we have learned
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is that most of the material
in the universe
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is made of something
entirely different than you and me.
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But without it,
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the universe as we know it wouldn't exist.
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Everything we can see with telescopes
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makes up just about 15 percent
of the total mass in the universe.
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Everything else, 85 percent of it,
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doesn't emit or absorb light.
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We can't see it with our eyes,
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we can't detect it with radio waves
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or microwaves or any other kind of light.
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But we know it is there
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because of its influence
on what we can see.
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It's a little bit like,
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if you wanted to map
the surface of our planet
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and everything on it
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using this picture of the Earth
from space at night.
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You get some clues
from where the light is,
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but there's a lot that you can't see.
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Everything from people,
to mountain ranges.
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And you have to infer what is there
from these limited clues.
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We call this unseen stuff dark matter.
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Now, a lot of people
have heard of dark matter,
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but even if you have heard of it,
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it probably seems abstract,
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far away, probably even irrelevant.
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Well, the interesting this is,
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dark matter is all around us
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and probably right here.
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In fact, dark matter particles
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are probably going through
your body right now
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as you sit in this room.
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Because we are on Earth
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and Earth is spinning around the Sun,
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and the Sun is hurdling through our galaxy
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at about half a million miles per hour.
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But dark matter doesn't bump into us,
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it just goes right through us.
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So how do we figure out more about this?
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What is it
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and what does it have to do
with our existence?
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Well, in order to figure out
how we came to be,
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we first need to understand
how our galaxy came to be.
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This is a picture of our galaxy,
the Milky Way, today.
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What did it look like
10 billion years in the past
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or what would it look like
10 billion years in the future?
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What about the stories
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of the hundreds of millions
of other galaxies
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that we've already mapped out
with large surveys of the sky?
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How would their histories be different
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if the universe was made of something else
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or if there was more or less matter in it?
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So the interesting thing
about these model universes
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is that they allow us
to test these possibilities.
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Let's go back to the first
moment of the universe.
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Just a fraction of a second
after the big bang.
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In this first moment,
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there was no matter at all.
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The universe was expanding very fast.
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And quantum mechanics tells us
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that matter is being created and destroyed
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all the time, in every moment.
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At this time, the universe
was expanding so fast,
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that the matter that got created
couldn't get destroyed.
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And thus we think that all of the matter
was created during this time.
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Both the dark matter
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and the regular matter
that makes up you and me.
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Now, let's go a little bit further
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to a time after the matter was created,
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after protons and neutrons formed,
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after hydrogen formed,
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about 400,000 years after the big bang.
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The universe was hot and dense
and really smooth,
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but not perfectly smooth.
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This image, taken with a space telescope
called the Planck satellite
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shows us the temperature of the universe
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in all directions.
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And what we see
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is that there were places
that were a little bit hotter
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and denser than others.
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The spots in this image
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represent places where there was
more or less mass in the early universe.
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Those spots got big because of gravity.
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The universe was expanding
and getting less dense overall
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over the last 13.8 billion years.
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But gravity worked hard in those spots
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where there was a little bit more mass,
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and pulled more and more mass
into those regions.
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Now, all of this
is a little hard to imagine,
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so let me just show you
what I am talking about.
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Those computer models I mentioned
allow us to test these ideas,
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so let's take a look at one of them.
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This movie. made by my research group,
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shows us what happened to the universe
after its earliest moments.
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You see the universe
started out pretty smooth,
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but there were some regions
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where there was a little bit
more material.
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Gravity turned on
and brought more and more mass
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into those spots that started out
with a little bit extra.
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Over time,
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you get enough stuff in one place
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that the hydrogen gas,
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which was initially well mixed
with the dark matter
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starts to separate from it,
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cool down, form stars,
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and you get a small galaxy.
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Over time, over billions
and billions of years,
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those small galaxies crash into each other
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and merge and grow
to become larger galaxies,
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like our own galaxy, the Milky Way.
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Now, what happens
if you don't have dark matter?
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If you don't have dark matter,
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those spots never get clumpy enough.
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It turns out, you need at least
a million times the mass of the Sun
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in one dense region,
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before you can start forming stars.
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And without dark matter,
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you never get enough stuff in one place.
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So here. we're looking
at two universes, side by side.
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In one of them you can see
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that things get clumpy quickly.
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In that universe,
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it's really easy to form galaxies.
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In the other universe,
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the things that start out
like small clumps,
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they just stay really small.
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Not very much happens.
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In that universe,
you wouldn't get our galaxy.
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Or any other galaxy.
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You wouldn't get the Milky Way,
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you wouldn't get the Sun,
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you wouldn't get us.
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We just couldn't exist in that universe.
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OK, so this crazy stuff, dark matter,
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it's most of the mass in the universe,
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it's going through us right now,
we wouldn't be here without it.
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What is it?
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Well, we have no idea.
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(Laughter)
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But we have a lot of educated guesses,
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and a lot of ideas
for how to find out more.
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So, most physicists think
that dark matter is a particle,
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similar in many ways to the subatomic
particles that we know of,
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like protons and neutrons and electrons.
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Whatever it is,
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it behaves very similarly
with respect to gravity.
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But it doesn't emit or absorb light,
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and it goes right through normal matter,
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as if it wasn't even there.
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We'd like to know what particle it is.
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For example, how heavy is it?
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Or, does anything at all happen
if it interacts with normal matter?
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Physicists have lots of great ideas
for what it could be,
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they are very creative.
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But it's really hard,
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because those ideas span a huge range.
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It could be as small
as the smallest subatomic particles,
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or it could be as large
as the mass of 100 Suns.
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So, how do we figure out what it is?
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Well, physicists and astronomers
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have a lot of ways
to look for dark matter.
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One of the things we're doing
is building sensitive detectors
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in deep underground mines,
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waiting for the possibility
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that a dark matter particle,
which goes through us an the Earth,
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would hit a denser material
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and leave behind
some trace of its passage.
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We're looking for dark matter in the sky,
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for the possibility
that dark matter particles
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would crash into each other,
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and create high-energy light
that we could see
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with special gamma-ray telescopes.
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We're even trying to make
dark matter here on Earth,
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by smashing particles together
and looking for what happens,
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using the Large Hadron
Collider in Switzerland.
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Now, so far,
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all of these experiments
have taught us a lot
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about what dark matter isn't,
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(Laughter)
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but not yet what it is.
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There were really good ideas
that dark matter could have been,
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that these experiments would have seen.
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And they didn't see them yet,
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so we have to keep looking
and thinking harder.
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Now, another way to get a clue
to what dark matter is,
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is to study galaxies.
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We already talked about
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how our galaxy and many other galaxies
wouldn't even be here
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without dark matter.
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Those models also make predictions
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for many other things about galaxies:
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How they're distributed in the universe,
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how they move,
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how they evolve over time.
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And we can test those predictions
with observations of the sky.
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So let me just give you two examples
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of these kinds of measurements
we can make with galaxies.
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The first is that we can make
maps of the universe with galaxies.
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I am part of a survey
called the Dark Energy Survey,
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which has made the largest map
of the universe so far.
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We measured the positions and shapes
of 100 million galaxies
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over one-eight of the sky.
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And this map is showing us all the matter
in this region of the sky,
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which is inferred by the light
distorted from these 100 million galaxies.
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The light distorted from all of the matter
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that was between those galaxies and us.
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The gravity of the matter is strong enough
to bend the path of light.
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And it gives us this image.
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So these kinds of maps
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can tell us about how much
dark matter there is,
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they also tell us where it is,
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and how it changes over time.
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So we're trying to learn
about what the universe is made of
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on the very largest scales.
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It turns out that the tiniest
galaxies in the universe
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provide some of the best clues.
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So why is that?
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Here are two example simulated universes
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with two different kinds of dark matter.
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Both of these pictures
are showing you a region
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around a galaxy like the Milky Way.
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And you can see that there's a lot
of other material around it,
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little small clumps.
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Now, in the image on the right,
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dark matter particles are moving slower
than they are in the one on the left.
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If those dark matter particles
are moving really fast,
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then the gravity in small clumps
is not strong enough
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to slow those fast particles down.
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And they keep going.
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They never collapse
into these small clumps.
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So you end up with fewer of them
than in the universe on the right.
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If you don't have those small clumps,
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then you get fewer small galaxies.
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If you look up at the southern sky,
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you can actually see two
of these small galaxies,
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the largest of the small galaxies
that are orbiting our Milky Way,
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the Large Magellanic Cloud
and the Small Magellanic Cloud.
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In the last several years,
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we have detected a whole bunch more
even smaller galaxies.
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This is an example of one of them
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that we detected with the same
dark energy survey
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that we used to make maps
of the universe.
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These really small galaxies,
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some of them are extremely small.
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Some of them have as few
as a few hundred stars,
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compared to the few hundred
billion stars in our Milky Way.
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So that makes them really hard to find.
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But in the last decade,
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we've actually found
a whole bunch more of these.
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We now know of 60 of these tiny galaxies
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that are orbiting our own Milky Way.
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And these little guys
are a big clue to dark matter.
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Because just the existence
of these galaxies tells us
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that dark matter
can't be moving very fast,
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and not much can be happening
when it runs in to normal matter.
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In the next several years,
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we're going to make much more
precise maps of the sky.
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And those will help refine our movies
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of the whole universe
and the entire galaxy.
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Physicists are also making new,
more sensitive experiments
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to try to catch some sign
of dark matter in their laboratories.
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Dark matter is still a huge mystery.
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But it's a really exciting time
to be working on it.
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We have really clear evidence it exists.
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From the scale of the smallest galaxies,
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to the scale of the whole universe.
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Will we actually find it
and figure out what it is?
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I have no idea.
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But it's going to be
a lot of fun to find out.
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We have a lot of possibilities
for discovery,
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and we definitely will learn more
about what it is doing
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and about what it isn't.
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Regardless of whether we find
that particle anytime soon,
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I hope I have convinced you
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that this mystery is actually
really close to home.
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The search for dark matter
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may just be the key to a whole new
understanding of physics
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and our place in the universe.
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Thank you.
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(Applause)
closed TED
