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85% of the matter in our universe
is a mystery.
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We don't know what it's made of,
which is why we call it dark matter.
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But we know it's out there because we
can observe its gravitational attraction
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on galaxies and other celestial objects.
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We've yet to directly observe dark matter,
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but scientists theorize that we may
actually be able to create it
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in the most powerful particle collider
in the world.
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That's the 27 kilometer-long
Large Hadron Collider, or LHC,
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in Geneva, Switzerland.
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So how would that work?
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In the LHC, two proton beams
move in opposite directions
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and are accelerated
to near the speed of light.
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At four collision points, the beams cross
and protons smash into each other.
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Protons are made of much smaller
components called quarks and gluons
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In most ordinary collisions, the two
protons pass through each other
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without any significant outcome.
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However, in about
one in a million collisions,
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two components hit each other
so violently,
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that most of the collision energy
is set free
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producing thousands of new particles.
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It's only in these collisions that very
massive particles,
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like the theorized dark matter,
can be produced.
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The collision points
are surrounded by detectors
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containing about 100 million sensors.
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Like huge three-dimensional cameras,
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they gather information
on those new particles,
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including their trajectory,
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electrical charge,
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and energy.
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Once processed, the computers can depict
a collision as an image.
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Each line is the path
of a different particle,
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and different types of particles
are color-coded.
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Data from the detectors
allows scientists to determine
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what each of these particles is,
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things like photons and electrons.
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Now, the detectors take snapshots of about
a billion of these collisions per second
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to find signs of extremely rare
massive particles.
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To add to the difficulty,
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the particles we're looking for
may be unstable
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and decay into more familiar particles
before reaching the sensors.
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Take, for example, the Higgs boson,
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a long-theorized particle that wasn't
observed until 2012.
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The odds of a given collision producing
a Higgs boson are about one in 10 billion,
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and it only lasts for
a tiny fraction of a second
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before decaying.
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But scientists developed theoretical
models to tell them what to look for.
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For the Higgs, they thought it would
sometimes decay into two photons.
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So they first examined only
the high-energy events
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that included two photons.
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But there's a problem here.
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There are innumerable
particle interactions
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that can produce two random photons.
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So how do you separate out the Higgs
from everything else?
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The answer is mass.
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The information gathered by the detectors
allows the scientists to go a step back
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and determine the mass of whatever it was
that produced two photons.
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They put that mass value into a graph
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and then repeat the process
for all events with two photons.
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The vast majority of these events
are just random photon observations,
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what scientists call background events.
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But when a Higgs boson is produced
and decays into two photons,
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the mass always comes out to be the same.
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Therefore, the tell-tale sign
of the Higgs boson
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would be a little bump sitting on top
of the background.
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It takes billions of observations
before a bump like this can appear,
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and it's only considered
a meaningful result
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if that bump becomes significantly
higher than the background.
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In the case of the Higgs boson,
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the scientists at the LHC announced their
groundbreaking result
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when there was only
a one in 3 million chance
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this bump could have
appeared by a statistical fluke.
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So back to the dark matter.
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If the LHC's proton beams have enough
energy to produce it,
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that's probably an even rarer occurrence
than the Higgs boson.
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So it takes quadrillions of collisions
combined with theoretical models
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to even start to look.
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That's what the LHC is currently doing.
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By generating a mountain of data,
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we're hoping to find more tiny bumps
in graphs
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that will provide evidence for
yet unknown particles, like dark matter.
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Or maybe what we'll
find won't be dark matter,
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but something else
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that would reshape our understanding
of how the universe works entirely.
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That's part of the fun at this point.
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We have no idea what we're
going to find.
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