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From DNA to Silly Putty, the diverse world of polymers - Jan Mattingly

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    What do silk,
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    DNA,
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    wood,
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    balloons,
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    and Silly Putty all have in common?
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    They're polymers.
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    Polymers are such a big part of our lives
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    that it's virtually impossible
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    to imagine a world without them,
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    but what the heck are they?
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    Polymers are large molecules
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    made of small units called monomers
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    linked together like the railroad cars from a train.
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    Poly means many,
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    and mono means one,
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    and mers or mero means parts.
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    Many polymers are made by repeating
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    the same small monomer over and over again
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    while others are made from two monomers
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    linked in a pattern.
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    All living things are made of polymers.
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    Some of the organic molecules in organisms
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    are small and simple,
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    having only one of a few functional groups.
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    Others, especially those that play structural roles
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    or store genetic information,
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    are macromolecules.
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    In many cases, these macromolecules are polymers.
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    For example, complex carbohydrates
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    are polymers of simple sugars,
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    proteins are polymers of amino acids,
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    and nucleic acids, DNA and RNA,
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    which contain our genetic information,
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    are polymers of nucleotides.
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    Trees and plants are made
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    of the polymer cellulose.
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    It's the tough stuff you find in bark and stems.
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    Feathers,
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    fur,
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    hair,
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    and fingernails
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    are made up of the protein keratin,
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    also a polymer.
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    It doesn't stop there.
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    Did you know that the exoskeletons
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    of the largest phylum in the animal kingdom,
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    the arthropods,
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    are made of the polymer chitin?
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    Polymers also form the basis
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    for synthetic fibers, rubbers, and plastics.
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    All synthetic polymers are derived from petroleum oil
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    and manufactured through chemical reactions.
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    The two most common types of reactions
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    used to make polymers
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    are addition reactions
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    and condensation reactions.
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    In addition reactions,
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    monomers simply add together to form the polymer.
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    The process starts with a free radical,
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    a species with an unpaired electron.
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    The free radical attacks
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    and breaks the bonds to form new bonds.
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    This process repeats over and over
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    to create a long-chained polymer.
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    In condensation reactions,
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    a small molecule, such as water,
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    is produced with each chain-extending reaction.
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    The first synthetic polymers
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    were created by accident
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    as by-products of various chemical reactions.
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    Thinking they were useless,
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    chemists mostly discarded them.
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    Finally, one named Leo Baekeland
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    decided maybe his useless by-product
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    wasn't so useless after all.
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    His work resulted in a plastic
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    that could be permanently squished into a shape
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    using pressure and high temperatures.
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    Since the name of this plastic,
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    polyoxybenzylmethylenglycolanhydride,
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    wasn't very catchy,
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    advertisers called it Bakelite.
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    Bakelite was made into telephones,
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    children's toys,
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    and insulators for electrical devices.
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    With its development in 1907,
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    the plastics industry exploded.
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    One other familiar polymer, Silly Putty,
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    was also invented by accident.
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    During World War II,
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    the United States was in desperate need
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    of synthetic rubber to support the military.
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    A team of chemists at General Electric
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    attempted to create one
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    but ended up with a gooey, soft putty.
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    It wasn't a good rubber substitute,
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    but it did have one strange quality:
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    it appeared to be extremely bouncy.
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    Silly Putty was born!
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    Synthetic polymers have changed the world.
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    Think about it.
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    Could you imagine getting through a single day
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    without using plastic?
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    But polymers aren't all good.
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    Styrofoam, for example, is made mainly of styrene,
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    which has been identified as a possible carcinogen
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    by the Environmental Protection Agency.
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    As Styrofoam products are being made,
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    or as they slowly deteriorate in landfills or the ocean,
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    they can release toxic styrene
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    into the environment.
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    In addition, plastics that are created
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    by addition polymerization reactions,
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    like Styrofoam,
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    plastic bags,
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    and PVC,
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    are built to be durable and food-safe,
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    but that means that they don't break down
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    in the environment.
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    Millions of tons of plastics
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    are dumped into landfills every year.
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    This plastic doesn't biodegrade,
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    it just breaks down
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    into smaller and smaller pieces,
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    affecting marine life
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    and eventually making their way back to humans.
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    Polymers can be soft or hard,
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    squishy or solid,
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    fragile or strong.
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    The huge variation between
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    means they can form
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    an incredibly diverse array of substances,
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    from DNA
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    to nylon stockings.
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    Polymers are so useful
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    that we've grown to depend on them every day.
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    But some are littering
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    our oceans, cities, and waterways
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    with effects on our health
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    that we're only beginning to understand.
Title:
From DNA to Silly Putty, the diverse world of polymers - Jan Mattingly
Description:

View full lesson: http://ed.ted.com/lessons/from-dna-to-silly-putty-the-diverse-world-of-polymers-jan-mattingly

You are made of polymers, and so are trees and telephones and toys. A polymer is a long chain of identical molecules (or monomers) with a range of useful properties, like toughness or stretchiness -- and it turns out, we just can't live without them. Polymers occur both naturally -- our DNA is a polymer -- and synthetically, like plastic, Silly Putty and styrofoam. Jan Mattingly explains how polymers have changed our world.

Lesson by Jan Mattingly, animation by TED-Ed.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
05:00

English subtitles

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