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The coldest materials in the world
aren’t in Antarctica.
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They’re not at the top of Mount Everest
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or buried in a glacier.
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They’re in physics labs:
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clouds of gases held just fractions
of a degree above absolute zero.
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That’s 395 million times colder
than your refrigerator,
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100 million times colder
than liquid nitrogen,
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and 4 million times colder
than outer space.
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Temperatures this low give scientists a
window into the inner workings of matter,
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and allow engineers to build
incredibly sensitive instruments
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that tell us more about everything
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from our exact position on the planet
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to what’s happening in
the farthest reaches of the universe.
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How do we create such
extreme temperatures?
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In short, by slowing down
moving particles.
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When we’re talking about temperature,
what we’re really talking about is motion.
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The atoms that make up solids,
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liquids,
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and gasses
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are moving all the time.
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When atoms are moving more rapidly,
we perceive that matter as hot.
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When they’re moving more
slowly, we perceive it as cold.
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To make a hot object
or gas cold in everyday life,
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we place it in a colder environment,
like a refrigerator.
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Some of the atomic motion in the hot
object is transferred to the surroundings,
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and it cools down.
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But there’s a limit to this:
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even outer space is too warm
to create ultra-low temperatures.
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So instead, scientists figured out a way
to slow the atoms down directly –
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with a laser beam.
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Under most circumstances,
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the energy in a laser beam
heats things up.
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But used in a very precise way,
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the beam’s momentum can stall
moving atoms, cooling them down.
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That’s what happens in a device
called a magneto-optical trap.
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Atoms are injected into a vacuum chamber,
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and a magnetic field
draws them towards the center.
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A laser beam aimed
at the middle of the chamber
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is tuned to just the right frequency
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that an atom moving towards it will absorb
a photon of the laser beam and slow down.
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The slow down effect comes from
the transfer of momentum
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between the atom and the photon.
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A total of six beams,
in a perpendicular arrangement,
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ensure that atoms traveling
in all directions will be intercepted.
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At the center, where the beams intersect,
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the atoms move sluggishly
as if trapped in a thick liquid —
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an effect the researchers who invented it
described as “optical molasses.”
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A magneto-optical trap like this
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can cool atoms down
to just a few microkelvins —
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about -273 degrees Celsius.
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This technique was developed in the 1980s,
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and the scientists
who'd contributed to it
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won the Nobel Prize in Physics in 1997
for the discovery.
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Since then, laser cooling has been
improved to reach even lower temperatures.
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But why would you want
to cool atoms down that much?
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First of all, cold atoms can make
very good detectors.
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With so little energy,
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they’re incredibly sensitive
to fluctuations in the environment.
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So they’re used in devices that find
underground oil and mineral deposits,
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and they also make
highly accurate atomic clocks,
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like the ones used
in global positioning satellites.
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Secondly, cold atoms hold
enormous potential
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for probing the frontiers of physics.
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Their extreme sensitivity
makes them candidates
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to be used to detect gravitational waves
in future space-based detectors.
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They’re also useful for the study
of atomic and subatomic phenomena,
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which requires measuring incredibly
tiny fluctuations in the energy of atoms.
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Those are drowned out
at normal temperatures,
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when atoms speed around
at hundreds of meters per second.
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Laser cooling can slow atoms to just
a few centimeters per second—
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enough for the motion caused by
atomic quantum effects to become obvious.
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Ultracold atoms have already
allowed scientists to study phenomena
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like Bose-Einstein condensation,
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in which atoms are cooled almost
to absolute zero
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and become a rare new state of matter.
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So as researchers continue in their quest
to understand the laws of physics
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and unravel the mysteries of the universe,
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they’ll do so with the help
of the very coldest atoms in it.