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| A superconductor. |
Actually, I’ll be writing about superconduct
ivity today, but superconduct
ors made a better title, and also
allowed me to use a clever graphic—lest we forget that these blogs are mostly
about keeping
me amused.
First, let’s have a couple demonstrations showing what
superconductivity is all about.
Demonstration 1.
Wave your hand about in the air as rapidly as you can. Now, move your hand just
as rapidly, but keeping your palm in firm contact with the surface of a carpet.
(Hey, I said firm contact.)
Okay, don’t be bleeding all over the carpet. So, do you feel
the heat on your palm? That heat is caused by friction with the surface of the
carpet as it resists the movement of your hand, what one might call (and I am calling) resistance.
Demonstration 2.
For this demonstration you will need your mother’s permission: pop a slice of
bread in your toaster (an English muffin would be better). Now crank that
handle down. (It’s plugged in, right?) Hold your horses, give it a few seconds.
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| Image** |
Now very carefully—don’t get too close—look down into the
toaster slot. (If your eyebrows are smoldering, you’re too close.) See those
glowing wires aligned on either side of the muffin? Those wires are made of a
metal alloy designed to resist the flow of electricity. That
resistance
to the electricity causes them to heat up, glow red and yellow, and hence the
delicious carmelization of the surface of the English muffin.
Now pop out that muffin, slather on a generous portion of margarine
or butter (see how it puddles deliciously in all the nooks and crannies?), add
a healthy dollop of jam, jelly or honey, and enjoy. In quantum mechanics, this
is referred to as a snack.
The wires in the toaster conduct electricity. (Starting
to see where we’re headed, eh?) They’re just designed to conduct it poorly, so there
is resistance, which causes heat, with some light as a byproduct. The same method
is used to create light in an incandescent light bulb—which is also why they’re
inefficient, because so much of the electricity ends up creating heat rather
than light.
On the other hand, most electric lines or wires are
designed to conduct electricity with as little resistance as possible, from the
cord connecting your computer to your house current to the high voltage
transmission lines that carry electricity from generating facilities to
distribution and transformer stations throughout the country.
There are two problems, however. First, all metal
wires—and there really aren’t any other kind in general use at present—have some
resistance to electric flow. Secondly, the lower the voltage of that flow, the
more susceptible it is to resistance.
So, to carry electricity over distances, power companies
raise the voltage to very high—and more dangerous—levels. Even so, it’s
estimated that upward of 5% of the power generated in this country is lost to
resistance before it even makes it to a consumer’s electric meter. To transmit
power at preferred lower voltages would result in exponentially higher losses.
At the opposite end of the spectrum, the flow of electricity
in the ever-smaller circuits of computers causes problems of speed, proximity
and heat that have our current technologies reaching their theoretical limits.
What physicists have sought, ever since electricity became
more than just a conjurer’s trick, was a means to conduct electricity at low
voltages without loss to resistance.
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| Image: American Superconductor |
In 1911, Dutch physicist (and Noble laureate) Heike Kamerlingh Onnes, who studied how
materials behaved at very low temperatures, discovered that, when super-cooled—and
by super-cooled I mean temperatures very close to absolute zero, -459.67
degrees Fahrenheit—some materials lost all resistance to electrical
conductivity. Hence the term, superconductors.
In theory, if one put an electrical current into a closed
loop of superconductive material, the electrical current would move unimpeded,
without any loss, through that loop indefinitely.
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| Image: ItsSaulConnected.com |
The problem remains, even 100 years later, that materials
still must be super-cooled to become superconductors, an expensive and
impractical consideration for general use. But research has been developing materials
that can superconduct at slightly warmer temperatures and the holy grail is
that material that can superconduct within ambient temperatures.
And I wouldn’t mind finding some way to toast my English
muffins faster.
[?]
