Please double-click on the English subtitles below to play the video.
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As a particle physicist, I study the elementary particles
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and how they interact on the most fundamental level.
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For most of my research career, I've been using accelerators,
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such as the electron accelerator at Stanford University, just up the road,
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to study things on the smallest scale.
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But more recently, I've been turning my attention
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to the universe on the largest scale.
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Because, as I'll explain to you,
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the questions on the smallest and the largest scale are actually very connected.
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So I'm going to tell you about our twenty-first-century view of the universe,
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what it's made of and what the big questions in the physical sciences are --
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at least some of the big questions.
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So, recently, we have realized
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that the ordinary matter in the universe --
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and by ordinary matter, I mean you, me,
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the planets, the stars, the galaxies --
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the ordinary matter makes up only a few percent
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of the content of the universe.
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Almost a quarter, or approximately a quarter
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of the matter in the universe, is stuff that's invisible.
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By invisible, I mean it doesn't absorb in the electromagnetic spectrum.
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It doesn't emit in the electromagnetic spectrum. It doesn't reflect.
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It doesn't interact with the electromagnetic spectrum,
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which is what we use to detect things.
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It doesn't interact at all. So how do we know it's there?
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We know it's there by its gravitational effects.
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In fact, this dark matter dominates
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the gravitational effects in the universe on a large scale,
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and I'll be telling you about the evidence for that.
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What about the rest of the pie?
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The rest of the pie is a very mysterious substance called dark energy.
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More about that later, OK.
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So for now, let's turn to the evidence for dark matter.
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In these galaxies, especially in a spiral galaxy like this,
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most of the mass of the stars is concentrated in the middle of the galaxy.
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This huge mass of all these stars keeps stars in circular orbits in the galaxy.
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So we have these stars going around in circles like this.
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As you can imagine, even if you know physics, this should be intuitive, OK --
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that stars that are closer to the mass in the middle will be rotating at a higher speed
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than those that are further out here, OK.
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So what you would expect is that if you measured the orbital speed of the stars,
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that they should be slower on the edges than on the inside.
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In other words, if we measured speed as a function of distance --
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this is the only time I'm going to show a graph, OK --
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we would expect that it goes down as the distance increases
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from the center of the galaxy.
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When those measurements are made,
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instead what we find is that the speed is basically constant,
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as a function of distance.
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If it's constant, that means that the stars out here
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are feeling the gravitational effects of matter that we do not see.
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In fact, this galaxy and every other galaxy
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appears to be embedded in a cloud of this invisible dark matter.
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And this cloud of matter is much more spherical than the galaxy themselves,
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and it extends over a much wider range than the galaxy.
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So we see the galaxy and fixate on that, but it's actually a cloud of dark matter
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that's dominating the structure and the dynamics of this galaxy.
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Galaxies themselves are not strewn randomly in space;
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they tend to cluster.
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And this is an example of a very, actually, famous cluster, the Coma cluster.
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And there are thousands of galaxies in this cluster.
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They're the white, fuzzy, elliptical things here.
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So these galaxy clusters -- we take a snapshot now,
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we take a snapshot in a decade, it'll look identical.
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But these galaxies are actually moving at extremely high speeds.
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They're moving around in this gravitational potential well of this cluster, OK.
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So all of these galaxies are moving.
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We can measure the speeds of these galaxies, their orbital velocities,
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and figure out how much mass is in this cluster.
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And again, what we find is that there is much more mass there
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than can be accounted for by the galaxies that we see.
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Or if we look in other parts of the electromagnetic spectrum,
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we see that there's a lot of gas in this cluster, as well.
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But that cannot account for the mass either.
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In fact, there appears to be about ten times as much mass here
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in the form of this invisible or dark matter
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as there is in the ordinary matter, OK.
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It would be nice if we could see this dark matter a little bit more directly.
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I'm just putting this big, blue blob on there, OK,
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to try to remind you that it's there.
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Can we see it more visually? Yes, we can.
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And so let me lead you through how we can do this.
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So here's an observer:
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it could be an eye; it could be a telescope.
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And suppose there's a galaxy out here in the universe.
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How do we see that galaxy?
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A ray of light leaves the galaxy and travels through the universe
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for perhaps billions of years
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before it enters the telescope or your eye.
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Now, how do we deduce where the galaxy is?
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Well, we deduce it by the direction that the ray is traveling
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as it enters our eye, right?
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We say, the ray of light came this way;
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the galaxy must be there, OK.
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Now, suppose I put in the middle a cluster of galaxies --
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and don't forget the dark matter, OK.
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Now, if we consider a different ray of light, one going off like this,
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we now need to take into account
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what Einstein predicted when he developed general relativity.
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And that was that the gravitational field, due to mass,
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will deflect not only the trajectory of particles,
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but will deflect light itself.
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So this light ray will not continue in a straight line,
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but would rather bend and could end up going into our eye.
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Where will this observer see the galaxy?
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You can respond. Up, right?
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We extrapolate backwards and say the galaxy is up here.
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Is there any other ray of light
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that could make into the observer's eye from that galaxy?
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Yes, great. I see people going down like this.
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So a ray of light could go down, be bent
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up into the observer's eye,
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and the observer sees a ray of light here.
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Now, take into account the fact that we live in
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a three-dimensional universe, OK,
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a three-dimensional space.
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Are there any other rays of light that could make it into the eye?
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Yes! The rays would lie on a -- I'd like to see -- yeah, on a cone.
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So there's a whole ray of light -- rays of light on a cone --
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that will all be bent by that cluster
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and make it into the observer's eye.
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If there is a cone of light coming into my eye, what do I see?
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A circle, a ring. It's called an Einstein ring. Einstein predicted that, OK.
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Now, it will only be a perfect ring if the source, the deflector
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and the eyeball, in this case, are all in a perfectly straight line.
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If they're slightly skewed, we'll see a different image.
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Now, you can do an experiment tonight over the reception, OK,
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to figure out what that image will look like.
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Because it turns out that there is a kind of lens that we can devise,
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that has the right shape to produce this kind of effect.
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We call this gravitational lensing.
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And so, this is your instrument, OK.
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(Laughter).
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But ignore the top part.
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It's the base that I want you to concentrate, OK.
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So, actually, at home, whenever we break a wineglass,
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I save the bottom, take it over to the machine shop.
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We shave it off, and I have a little gravitational lens, OK.
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So it's got the right shape to produce the lensing.
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And so the next thing you need to do in your experiment
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is grab a napkin. I grabbed a piece of graph paper -- I'm a physicist. (Laughter)
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So, a napkin. Draw a little model galaxy in the middle.
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And now put the lens over the galaxy,
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and what you'll find is that you'll see a ring, an Einstein ring.
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Now, move the base off to the side,
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and the ring will split up into arcs, OK.
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And you can put it on top of any image.
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On the graph paper, you can see
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how all the lines on the graph paper have been distorted.
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And again, this is a kind of an accurate model
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of what happens with the gravitational lensing.
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OK, so the question is: do we see this in the sky?
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Do we see arcs in the sky when we look at, say, a cluster of galaxies?
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And the answer is yes.
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And so, here's an image from the Hubble Space Telescope.
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Many of the images you are seeing
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are earlier from the Hubble Space Telescope.
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Well, first of all, for the golden shape galaxies --
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those are the galaxies in the cluster.
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They're the ones that are embedded in that sea of dark matter
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that are causing the bending of the light
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to cause these optical illusions, or mirages, practically,
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of the background galaxies.
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So the streaks that you see, all these streaks,
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are actually distorted images of galaxies that are much further away.
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So what we can do, then, is based on how much distortion
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we see in those images, we can calculate how much mass
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there must be in this cluster.
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And it's an enormous amount of mass.
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And also, you can tell by eye, by looking at this,
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that these arcs are not centered on individual galaxies.
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They are centered on some more spread out structure,
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and that is the dark matter
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in which the cluster is embedded, OK.
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So this is the closest you can get to kind of seeing
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at least the effects of the dark matter with your naked eye.
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OK, so, a quick review then, to see that you're following.
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So the evidence that we have
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that a quarter of the universe is dark matter --
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this gravitationally attracting stuff --
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is that galaxies, the speed with which stars orbiting galaxies
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is much too large; it must be embedded in dark matter.
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The speed with which galaxies within clusters are orbiting is much too large;
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it must be embedded in dark matter.
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And we see these gravitational lensing effects, these distortions
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that say that, again, clusters are embedded in dark matter.
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OK. So now, let's turn to dark energy.
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So to understand the evidence for dark energy, we need to discuss something
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that Stephen Hawking referred to in the previous session.
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And that is the fact that space itself is expanding.
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So if we imagine a section of our infinite universe --
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and so I've put down four spiral galaxies, OK --
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and imagine that you put down a set of tape measures,
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so every line on here corresponds to a tape measure,
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horizontal or vertical, for measuring where things are.
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If you could do this, what you would find
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that with each passing day, each passing year,
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each passing billions of years, OK,
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the distance between galaxies is getting greater.
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And it's not because galaxies are moving
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away from each other through space.
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They're not necessarily moving through space.
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They're moving away from each other
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because space itself is getting bigger, OK.
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That's what the expansion of the universe or space means.
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So they're moving further apart.
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Now, what Stephen Hawking mentioned, as well,
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is that after the Big Bang, space expanded at a very rapid rate.
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But because gravitationally attracting matter
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is embedded in this space,
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it tends to slow down the expansion of the space, OK.
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So the expansion slows down with time.
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So, in the last century, OK, people debated
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about whether this expansion of space would continue forever;
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whether it would slow down, you know,
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will be slowing down, but continue forever;
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slow down and stop, asymptotically stop;
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or slow down, stop, and then reverse, so it starts to contract again.
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So a little over a decade ago,
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two groups of physicists and astronomers
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set out to measure the rate at which
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the expansion of space was slowing down, OK.
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By how much less is it expanding today,
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compared to, say, a couple of billion years ago?
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The startling answer to this question, OK, from these experiments,
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was that space is expanding at a faster rate today
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than it was a few billion years ago, OK.
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So the expansion of space is actually speeding up.
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This was a completely surprising result.
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There is no persuasive theoretical argument for why this should happen, OK.
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No one was predicting ahead of time this is what's going to be found.
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It was the opposite of what was expected.
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So we need something to be able to explain that.
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Now it turns out, in the mathematics,
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you can put it in as a term that's an energy,
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but it's a completely different type of energy
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from anything we've ever seen before.
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We call it dark energy,
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and it has this effect of causing space to expand.
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But we don't have a good motivation
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for putting it in there at this point, OK.
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So it's really unexplained as to why we need to put it in.
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Now, so at this point, then, what I want to really emphasize to you,
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is that, first of all, dark matter and dark energy
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are completely different things, OK.
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There are really two mysteries out there as to what makes up most of the universe,
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and they have very different effects.
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Dark matter, because it gravitationally attracts,
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it tends to encourage the growth of structure, OK.
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So clusters of galaxies will tend to form,
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because of all this gravitational attraction.
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Dark energy, on the other hand,
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is putting more and more space between the galaxies,
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makes it, the gravitational attraction between them decrease,
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and so it impedes the growth of structure.
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So by looking at things like clusters of galaxies,
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and how they -- their number density,
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how many there are as a function of time --
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we can learn about how dark matter and dark energy
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compete against each other in structure forming.
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In terms of dark matter, I said that we don't have any,
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you know, really persuasive argument for dark energy.
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Do we have anything for dark matter? And the answer is yes.
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We have well-motivated candidates for the dark matter.
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Now, what do I mean by well motivated?
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I mean that we have mathematically consistent theories
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that were actually introduced
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to explain a completely different phenomenon, OK,
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things that I haven't even talked about,
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that each predict the existence
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of a very weakly interacting, new particle.
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So, this is exactly what you want in physics:
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where a prediction comes out of a mathematically consistent theory
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that was actually developed for something else.
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But we don't know if either of those
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are actually the dark matter candidate, OK.
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One or both, who knows? Or it could be something completely different.
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Now, we look for these dark matter particles
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because, after all, they are here in the room, OK,
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and they didn't come in the door.
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They just pass through anything.
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They can come through the building, through the Earth --
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they're so non-interacting.
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So one way to look for them is to build detectors
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that are extremely sensitive to a dark matter particle coming through and bumping it.
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So a crystal that will ring if that happens.
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So one of my colleagues up the road and his collaborators
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have built such a detector.
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And they've put it deep down in an iron mine in Minnesota,
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OK, deep under the ground, and in fact, in the last couple of days
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announced the most sensitive results so far.
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They haven't seen anything, OK, but it puts limits on what the mass
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and the interaction strength of these dark matter particles are.
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There's going to be a satellite telescope launched later this year
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and it will look towards the middle of the galaxy,
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to see if we can see dark matter particles annihilating
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and producing gamma rays that could be detected with this.
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The Large Hadron Collider, a particle physics accelerator,
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that we'll be turning on later this year.
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It is possible that dark matter particles might be produced
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at the Large Hadron Collider.
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Now, because they are so non-interactive,
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they will actually escape the detector,
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so their signature will be missing energy, OK.
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Now, unfortunately, there is a lot of new physics
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whose signature could be missing energy,
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so it will be hard to tell the difference.
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And finally, for future endeavors, there are telescopes being designed
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specifically to address the questions of dark matter and dark energy --
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ground-based telescopes, and there are three space-based telescopes
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that are in competition right now
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to be launched to investigate dark matter and dark energy.
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So in terms of the big questions:
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what is dark matter? What is dark energy?
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The big questions facing physics.
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And I'm sure you have lots of questions,
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which I very much look forward to addressing
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over the next 72 hours, while I'm here. Thank you.
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(Applause)
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