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Consider throwing a ball
straight into the air.
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Can you predict the motion
of the ball after it leaves your hand?
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Sure, that's easy.
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The ball will move upward
until it gets to some highest point,
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then it will come back down
and land in your hand again.
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Of course that's what happens,
-
and you know this because you have
witnessed events like this countless times.
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You've been observing the physics
of everyday phenomena your entire life.
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But suppose we explore a question
about the physics of atoms
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like, what does the motion of an electron
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around the nucleus of a
hydrogen atom look like?
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Could we answer that question based on
our experience with everyday physics?
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Definietly not. Why?
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Because the physics that governs the
behavior of systems at such small scales
-
is much different than the physics
of the macroscopic objects
-
you see around you all the time.
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The everyday world you know and love
-
behaves according to the laws
of classical mechanics.
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But systems on the scale of atoms
-
behave according to the laws
of quantum mechanics.
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This quantum world turns out to be
a very strange place.
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An illustration of quantum strangeness
is given by a famous thought experiment:
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Shrodinger's Cat.
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A physicist, who doesn't particularly
like cats, puts a cat in a box,
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along with a bomb that has a 50% chance
of blowing up after the lid is closed.
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Until we reopen the lid,
there is no way of knowing
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whether the bomb exploded or not,
-
and thus, no way of knowing
if the cat is alive or dead.
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In quantum physics,
we could say that before our observation
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the cat was in a superposition state.
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It was neither alive nor dead but
rather in a mixture of both possibilities,
-
with a 50% chance for each.
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The same sort of thing happens
to physical systems at quantum scales,
-
like an electron orbiting
in a hydrogen atom.
-
The electron isn't really orbiting at all.
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It's sort of everywhere in space,
all at once,
-
with more of a probability of being
at some places than others,
-
and it's only after
we measure its position
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that we can pinpoint where it is
at that moment.
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A lot like how we didn't know
whether that cat was alive or dead
-
until we opened the box.
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This brings us to the strange
and beautiful phenomenon
-
of quantum entanglement.
-
Suppose that instead of one cat in a box,
we have two cats in two different boxes.
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If we repeat the Schrodinger's Cat
experiment with this pair of cats,
-
the outcome of the experiment
can be one of four possibilites.
-
Either both cats will be alive,
or both will be dead,
-
or one will be alive
and the other dead, or vic versa.
-
The system of both cats
is again in a superposition state,
-
with each outcome having a 25% chance
rather than 50%.
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But here's the cool thing.
-
Quantum mechanics tells us
it's possible to erase
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the both cats alive and both cats dead
outcomes from the superposition state.
-
In other words,
there can be a two cat system
-
such that the outcome will always be
one cat alive and the other cat dead.
-
The technical term for this is that the
states of the cats are entangled.
-
But there's something truly mindblowing
about quantum entanglement.
-
If you prepare the system of two cats
in boxes in this entangled state,
-
then move the boxes to opposite
ends of the universe,
-
the outcome of the experiment
will still always be the same.
-
One cat will always come out alive,
and the other cat will always end up dead,
-
even though which particular cat
lives or dies is completely undetermined
-
before we measure the outcome.
-
How is this possible?
-
How is it that the states of cats
on opposite sides of the universe
-
can be entangled in this way?
-
They're too far away to communicate
with each other in time,
-
so how do the two bombs always
conspire such that
-
one blows up and the other doesn't?
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You might be thinking,
-
"This is just some theoretical
mumbo jumbo.
-
This sort of thing can't happen
in the real world".
-
But it turns out that quantum entanglement
-
has been confirmed in
real world lab experiments.
-
Two subatomic particles entangled
in a superposition state,
-
where if one spins one way
then the other must spin the other way,
-
will do just that,
even when there's no way
-
for information to pass
from one particle to the other
-
indicating which way to spin
to obey the rules of entanglement.
-
It's not surprising then that
entanglement is at the core
-
of quantum information science,
-
a growing field studying how to use
the laws of the strange quantum world
-
in our macroscopic world,
-
like in quantum cryptography, so spies
can send secure messages to each other,
-
or quantum computing,
for cracking secret codes.
-
Everyday physics may start to look
a bit more like the strange quantum world.
-
Quantum teleportation
may even progress so far,
-
that one day your cat will
escape to a safer galaxy,
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where there are no physicists,
and no boxes.
closed TED
