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| photo by StockSnap - public domain |
Because inquiring eight-year-olds want to know!
Before we proceed, a few definitions –
A Skittle is an M&M-looking candy-coated chewy sugar
rush, for which you may have heard the ad campaign, Taste the Rainbow,
or the more evocative Experience the Rainbow.
(By the way, put a
Skittle or M&M in water and watch the coating dissolve except for the “S”
or “M” which floats to the top. Yum!)
The hammer we mean is just the basic clawed type you have in
your toolbox for bashing nails, thumbs and absolute zero Skittles.
Absolute zero is presumably as cold as something can be, and
warrants a little further explanation than the former two ingredients.
Dude, that is cold.
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| photo by moritz320 - public domain |
Zero degrees Celsius is where water freezes, zero degrees Fahrenheit
is where I don’t let my kids go outside for very long, and zero degrees Kelvin
is absolute zero -- where molecules stop moving around. (Quick review – under normal circumstances, molecules
are always moving around. Faster in
gases, slower in solids, but we haven’t seen ‘em actually hold still yet.)
Now, absolute zero is not the complete absence of all movement. The super-frozen molecules don’t move, but
the particles within the atoms that make up the molecules are still moving
around in their usual way, just in their ground state. An atom’s ground state is its lowest-possible
energy state, so basically the electrons are being as chill as they can be, but
they’re still zinging around in their dizzying dance of quantum probability
(which we’ll mess with later on.)
Scientists have gotten some substances to within spittin’
distance of absolute zero, and when things get that cold, they often exhibit
bizarre behaviors, such as becoming superconductors (having no electrical
resistance) or superfluids (flowing without viscosity.) Helium superfluid can flow in an endless fountain, and superconductors’
magnetic fields can cause levitation.
So could you
super-freeze a Skittle?
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| photo by Heamer - public domain |
Getting complex molecules down to nuthin’-Kelvin is very
tricky. So far, gases have been the best
candidates.
Researchers at MIT got some sodium potassium molecules down to almost zero Kelvin, but
they had to assemble the molecules from their constituent atoms as they went
along. They found, though, that the
super-cold molecules were stable, long-lasting, and showed electric charge
imbalances that could produce a magnetic effect between molecules.
Professor Martin Zwierlein of MIT says that “with ultracold
molecules, you can get a huge variety of different states of matter, like
superfluid crystals, which are crystalline, yet feel no friction, which is
totally bizarre. This has not been observed so far, but predicted.”
Perhaps a Skittle would be a candidate for a superfluid
crystal, if the crystalline structure of sucrose would play any part. Figuring that a Skittle is mostly sugar,
we’re looking at a bunch of these molecules:
12 atoms of carbon, 22 atoms of hydrogen, and 11 atoms of oxygen
(C12H22O11)
-- a far cry from the two-atom item (NaK) put on deep freeze
at MIT.
Another group of scientists from the University of Colorado found
that their ultra-cold potassium rubidium (KRb) molecules flew apart upon
collision, so perhaps our Skittle would need some sort of containment to keep
it intact until the hammer hit.
So it’s hard to say for sure if our absolute zero Skittle
would just fall apart, become some superfluid soup of sugar components, or be
hard as a rock.
So hit it with a hammer, already!
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| photo by jackmac34 – public domain |
We did put a Skittle through a test run with a household
freezer and a household hammer, and in that case, it shattered admirably into many
non-uniform shards.
Our best guess at this point is that if a Skittle maintained
its cohesion through the cooling process, the hammer hit would raise the
temperature at the moment of impact by making the molecules move, and would
probably result in a very pulverized Skittle.
Unless said Skittle became an exotic state of matter first
and ascended to a realm beyond the mundane friction a hammer would
produce. You could have superfluid
crystal Skittle, or ether-Skittle or plasma-Skittle or
pile-of-atoms-that-used-to-be-a-Skittle -- just as elusive to experience as an
actual rainbow.
…Fade to black. “That concludes the regular physics version
of the answer. Thank you for
reading. Feel free to go home and freeze
a Skittle. Or…read on…”
Absolute Zero
Skittle: the Quantum Theory Fun Part
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| photo by geralt – public domain |
MIT’s Professor Zwierlein also said, “We are very close to
the temperature at which quantum mechanics plays a big role in the motion of
molecules, so these molecules would no longer run around like billiard balls,
but move as quantum mechanical matter waves."
Now we’re talking!
You see, quantum particles exist under a slightly different
set of rules than we big huge visible solid-looking things. Those teeny pieces move in such a way as to
function as both particles and waves, kind of fuzzy in their location, as if
occupying many spaces at once while moving too fast to be captured on film –
physicists generally determine their “location” by figuring out the probability
of where they most likely might be.
So let’s get theoretical with our Skittle.
As stated before, absolute zero is the state of having
chilled-out molecules but their constituent atoms still have energy; the atoms
are just in their ground state. Let’s
see what might happen, according to the chalkboard, if we slowed down our
Skittle until even the subatomic particles were not moving.*
There’s an odd and seemingly true (as far as we can tell)
feature of quantum physics called Heisenberg’s uncertainty principle, brought
to us in 1927 by theoretical physicist Werner Heisenberg.
Heisenberg wrote: "It seems to be a general law of
nature that we cannot determine position and velocity simultaneously with
arbitrary accuracy."
The uncertainty principle is general acknowledgment that we
just can’t make a precise statement about the where and where-to of a
fundamental particle; it’s exact position and state of motion (momentum) cannot
be simultaneously defined. Kinda goes
with the fact that a probability is as close as we get to pinpointing, say, an
electron. And even though it’s meant to
be an observation of an apparent limitation, the principle exists as a math
formula.
The actual equation for the uncertainty principle is
apparently pretty uncertain itself, if you survey the internet, so we’re going
to go with Stanford University’s take on it, as explained in the Stanford
Encyclopedia of (get this) Philosophy (quantum physics kind of belongs in the
philosophy circle, after all) right here!
This is why our Skittle is weird: δpδq ∼ h
…where δp = indetermination of particle's position, and δq =
indetermination of particle's momentum, and h = Planck’s constant, which is
6.626 x 10-34 joule seconds (i.e. a super teeny number.)**
So if just for fun we treat Heisenberg’s relation like a
straight-up math equation rather than a general statement about how much we
can’t know, we can figure this:
If all motion stopped, that is, if even the subatomic
particles held still, then the range in error of momentum (δq) would be zero
because its movement (i.e. lack thereof) would be absolutely known, and then
the range in error of position (δp) would have to make up for it by
becoming infinite.
Or as Heisenberg put it: "In a stationary state of an
atom its phase is in principle indeterminate."
Or as physicist Kenneth Ford explains: “Carried to a limit,
it even means that if you knew one quantity precisely, with perfect exactitude,
there is another quantity about which you would know nothing.”
Or as I put it: a Skittle at absolute-NO-motion-zero could
be… anywhere.***
*I care not that this is impossible by all accounts.
**Planck’s constant is a teeny number that’s proven to be
super useful in equations dealing with particle physics. A semi-related and similarly teeny number is
the Planck length (about 10-35m,) which has been described thus:
The number of Planck lengths that could be lined up across a
proton is comparable to the number of protons that could line up from Philadelphia
to New York!
I just had to share that.
***Yeah, yeah, it wouldn’t really happen that way… even when working with probability within
the uncertainty principle, you still have borders of sorts, like the quantum
Skittle would be mostly under the hammer and not all hanging out in Morocco and
Proxima Centauri…but as we say in particle physics and astrophysics,
“the math works out!”
