Silk is a
protein.
Like all proteins, it is a
polypeptide,
and it has a structure something like this:
You'll notice the segment highlighted in blue repeats over and over again. In a real protein
molecule, the repeat unit occurs hundreds of times, not just four times as shown here.
Scientists call giant molecules such as proteins
macromolecules,
or polymers.
The portion highlighted in blue is called the
repeat unit.
Nylon was designed to be a synthetic replacement for silk. So it isn't surprising that
the material Wallace Carothers invented has a structure very similar to that
of natural silk. Nylon 6-6 has a chemical structure like you see below. This picture shows
one repeat
unit, but in a real nylon macromolecule, many repeat units are linked together, as shown in the
picture on the left side of this page, and most every other page in this exhibit.
Nylon was developed as a synthetic substitute for silk. Silk is harvested from cocoons made by
silkworms, the larvae of the Asian moth Bombyx mori.
Take a closer look at the protein segment over on your right. The portion highlighted in red
is what chemists call an
amide
group. Amide groups have a lot to do with why silk
is such a wonderful fiber, as we'll see in just a moment. Macromolecules with amide groups in
their repeat units are called
polyamides.
Notice the amide groups in the structure. The amide groups are what make nylon such a good
fiber. Amide groups are strongly attracted to each other. When nylon is spun into fibers,
the long chain-like macromolecules line up parallel to each other. The amide groups on adjacent
chains then form strong bonds with each other called
hydrogen bonds.
These hydrogen bonds hold the adjacent chains together, making nylon yarn strong.
