The
Thermodynamics Of Rubber Bands
Heating generally expands a substance. Yet if you
heat up rubber bands, they shrink — and when they’re stretched they get hotter.
What’s going on?
Rubber Bands When things are heated, they spread
out. Whether it’s water, turning to steam and spreading through the atmosphere,
gas heating and pushing against the sides of its container, or a cat stretching
out in the sun; when it gets hot it expands. And yet, when you hold a hair
dryer up to rubber (or plastic), it shrivels like a salted slug. (Writer’s
note: This was a dramatic example used for effect and drawn from abstract
knowledge. Don’t pour salt on slugs, kids. It’s mean, and it will make your
future dates think that you might be a serial killer.)
Rubber has its structure to thank for its odd
reaction to heat. Water and gas are materials in which compact molecules form
tenuous bonds along fairly definite boundaries. Even in its solid form, ice,
water becomes a crystalline structure that can break apart cleanly. When
someone heats ice, the molecules of water start jiggling around faster and
faster. Eventually, they move fast enough to break apart and form water, and
then steam.
Rubber is different. It’s made from long,
string-like molecules. Instead of being placed in an orderly crystal, like
water, strings of rubber are tangled together. When rubber is heated, its
molecules do the same thing water molecules do; they jiggle around. Anyone who
has ever had to untangle Christmas lights knows that jiggling long segments of
string doesn’t make them break apart. If anything, they tangle together more
tightly. The same thing happens to rubber molecules. They move randomly, faster
and faster, and so they become more tightly snarled. They pull together and
contract into little balls, and so the rubber contracts.
Rubber and plastic heat when they’re stretched. This
is equally counterintuitive. When other materials are given more room, they
cool. There’s even a name for it; adiabatic cooling. To return to the example
of water; a cylinder full of steam is very hot. If the cylinder is compressed,
the gas will heat further. If the cylinder is expanded, the gas will
automatically cool. When stretching rubber, though, you are not giving the
molecules more room. They’re tangled together closely enough that pulling on
each end only forces the strands closer together. Since they are being squeezed
into a tighter space, the molecules move faster, and so they’re hotter.
To test this, stretch a rubber band and press it to
your forehead, lip, or wrist. The rubber will be hot. Let it contract again,
and suddenly the rubber will feel cool.
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