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What can Schrödinger's cat teach us about quantum mechanics? - Josh Samani

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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,
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    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
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    is much different than the physics
    of the macroscopic objects
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    you see around you all the time.
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    The everyday world you know and love
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    behaves according to the laws
    of classical mechanics.
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    But systems on the scale of atoms
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    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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    Schrödinger'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,
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    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,
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    with a 50% chance for each.
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    The same sort of thing happens
    to physical systems at quantum scales,
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    like an electron orbiting
    in a hydrogen atom.
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    The electron isn't really orbiting at all.
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    It's sort of everywhere in space,
    all at once,
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    with more of a probability of being
    at some places than others,
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    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 the cat was alive or dead
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    until we opened the box.
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    This brings us to the strange
    and beautiful phenomenon
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    of quantum entanglement.
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    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 Schrödinger's cat experiment
    with this pair of cats,
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    the outcome of the experiment
    can be one of four possibilities.
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    Either both cats will be alive,
    or both will be dead,
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    or one will be alive
    and the other dead, or vice versa.
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    The system of both cats
    is again in a superposition state,
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    with each outcome having a 25% chance
    rather than 50%.
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    But here's the cool thing:
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    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.
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    In other words,
    there can be a two cat system,
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    such that the outcome will always be
    one cat alive and the other cat dead.
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    The technical term for this is that the
    states of the cats are entangled.
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    But there's something truly mindblowing
    about quantum entanglement.
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    If you prepare the system of two cats
    in boxes in this entangled state,
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    then move the boxes to opposite
    ends of the universe,
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    the outcome of the experiment
    will still always be the same.
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    One cat will always come out alive,
    and the other cat will always end up dead,
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    even though which particular cat
    lives or dies is completely undetermined
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    before we measure the outcome.
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    How is this possible?
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    How is it that the states of cats
    on opposite sides of the universe
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    can be entangled in this way?
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    They're too far away to communicate
    with each other in time,
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    so how do the two bombs always
    conspire such that
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    one blows up and the other doesn't?
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    You might be thinking,
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    "This is just some theoretical
    mumbo jumbo.
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    This sort of thing can't happen
    in the real world."
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    But it turns out that quantum entanglement
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    has been confirmed in
    real world lab experiments.
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    Two subatomic particles entangled
    in a superposition state,
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    where if one spins one way
    then the other must spin the other way,
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    will do just that,
    even when there's no way
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    for information to pass
    from one particle to the other
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    indicating which way to spin
    to obey the rules of entanglement.
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    It's not surprising then that
    entanglement is at the core
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    of quantum information science,
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    a growing field studying how to use
    the laws of the strange quantum world
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    in our macroscopic world,
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    like in quantum cryptography, so spies
    can send secure messages to each other,
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    or quantum computing,
    for cracking secret codes.
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    Everyday physics may start to look
    a bit more like the strange quantum world.
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    Quantum teleportation
    may even progress so far,
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    that one day your cat will
    escape to a safer galaxy,
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    where there are no physicists
    and no boxes.
Title:
What can Schrödinger's cat teach us about quantum mechanics? - Josh Samani
Speaker:
Josh Samani
Description:

View full lesson: http://ed.ted.com/lessons/what-can-schrodinger-s-cat-teach-us-about-quantum-mechanics-josh-samani

The classical physics that we encounter in our everyday, macroscopic world is very different from the quantum physics that governs systems on a much smaller scale (like atoms). One great example of quantum physics’ weirdness can be shown in the Schrödinger's cat thought experiment. Josh Samani walks us through this experiment in quantum entanglement.

Lesson by Josh Samani, animation by Dan Pinto.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
05:24

English subtitles

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