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Pizza physics (New York-style) - Colm Kelleher

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    Pretty much everyone loves eating pizza,
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    but it can be a messy business.
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    Pizza is soft and bendable.
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    So how can you stop
    all that cheese from falling off?
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    You might know some tricks:
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    you can use two hands --
    not so classy,
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    or you can use a paper plate
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    and allow only the tip
    of the pizza to peek out.
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    There's one other trick, though:
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    holding the crust, you can sort
    of fold the slice down the middle.
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    Now the tip of the pizza
    isn't falling over,
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    and you can eat it without getting
    tomato sauce all over yourself
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    or accidentally biting off
    some of that paper plate.
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    But why should the tip stay up
    just because you bent the crust?
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    To understand this,
    you need to know two things:
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    a little bit about the math
    of curved shapes
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    and a little about the physics
    of thin sheets.
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    First, the math.
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    Suppose I have a flat sheet
    made out of rubber.
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    It's really thin and bendable,
    so it's easy to roll into a cylinder.
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    I don't need to stretch
    the sheet at all, just bend it.
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    This property where one shape
    can be transformed into another
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    without stretching or crumpling,
    is called isometry.
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    A mathematician would say that a flat
    sheet is isometric to a cylinder.
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    But not all shapes are isometric.
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    If I try to turn my flat sheet
    into part of a sphere,
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    there's no way I can do it.
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    You can check this for yourself,
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    by trying to fit a flat sheet
    of paper onto a soccer ball
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    without stretching or crumpling the paper.
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    It's just not possible.
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    So a mathematician would say
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    that a flat sheet and a sphere
    aren't isometric.
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    There's one more familiar
    shape that isn't isometric
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    to any of the shapes we've seen
    so far: a potato chip.
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    Potato chip shapes
    aren't isometric to flat sheets.
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    If you want to get a flat piece of rubber
    into the shape of a potato chip,
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    you need to stretch it --
    not just bend it, but stretch it as well.
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    So, that's the math.
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    Not so hard, right?
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    Now for the physics.
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    It can be summed up in one sentence:
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    Thin sheets are easy to bend
    but hard to stretch.
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    This is really important.
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    Thin sheets are easy to bend
    but hard to stretch.
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    Remember when we rolled
    our flat sheet of rubber into a cylinder?
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    That wasn't hard, right?
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    But imagine how hard
    you'd have pull on the sheet
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    to increase its area by 10 percent.
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    It would be pretty difficult.
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    The point is that bending a thin sheet
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    takes a relatively small amount of force,
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    but stretching or crumbling
    a thin sheet is much harder.
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    Now, finally, we get to talk about pizza.
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    Suppose you go down to the pizzeria
    and buy yourself a slice.
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    You pick it up from the crust,
    first, without doing the fold.
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    Because of gravity,
    the slice bends downwards.
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    Pizza is pretty thin, after all,
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    and we know that thin sheets
    are easy to bend.
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    You can't get it in your mouth,
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    cheese and tomato sauce dripping
    everywhere -- it's a big mess.
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    So you fold the crust.
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    When you do, you force the pizza
    into something like a taco shape.
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    That's not hard to do --
    after all, this shape is isometric
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    to the original pizza, which was flat.
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    But imagine what would happen
    if the pizza were to droop down
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    while you're bending it.
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    Now it looks like a droopy taco.
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    And what does a droopy taco
    look like? A potato chip!
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    But we know that potato chips are not
    isometric to flat pieces of rubber
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    or flat pizzas,
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    and that means that in order
    to get into the shape it's in now,
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    the slice of pizza had to stretch.
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    Since the pizza is thin,
    this takes a lot of force,
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    compared to the amount of force it takes
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    to bend the pizza in the first place.
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    So, what's the conclusion?
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    When you fold the pizza at the crust,
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    you make it into a shape where a lot
    of force is needed to bend the tip down.
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    Often gravity isn't strong enough
    to provide this force.
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    That was kind of a lot of information,
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    so let's do a quick backwards recap.
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    When pizza is folded at the crust,
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    gravity isn't strong enough
    to bend the tip.
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    Why? Because stretching a pizza is hard.
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    And to bend the tip downwards,
    the pizza would have to stretch,
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    because the shape the pizza would be in,
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    the droopy taco shape,
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    isn't isometric
    to the original flat pizza.
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    Why? Because of math.
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    As the pizza example shows,
    we can learn a lot
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    by looking at the mathematical properties
    of different shapes.
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    And it's especially nice when those shapes
    happen to be pizza slices.
Title:
Pizza physics (New York-style) - Colm Kelleher
Description:

View full lesson: http://ed.ted.com/lessons/pizza-physics-new-york-style-colm-kelleher

People love eating pizza, but every style of pie has a different consistency. If "New York-style" -- thin, flat and large -- is your texture of choice, then you've probably eaten a slice that was as messy as it was delicious. Colm Kelleher outlines the scientific and mathematical properties that make folding a slice the long way the best alternative ... to wearing a bib.

Talk by Colm Kelleher, animation by Joel Trussell.

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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
03:58

English subtitles

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