I'm late for my two week-appointment
with my blog, so here's something special.
- How logic in Quantum Mechanics
differs from the 'real world'.
Today I want to tell you one of the big
secrets of Quantum Mechanics, using a parallel with a cat in it. By
the time you have read this page (a couple of times) ordinary Quantum
Mechanics will hopefully be clear, if not, don't hesitate to ask.
Schrødinger's cat is another well known parallel with a cat, but it is about
something else (in Q.M.).
We all use probability in our daily
life, it's a handy tool. There is 1/6 chance of a die landing on a 6,
there is 1/2 chance of a slice of bread landing with the peanut-butter-side down on the floor. Here, common sense dictates
several wrong claims, like getting a 6 two times on a row (on a die)
makes a third 6 less probable. Forgetting those fallacies, we all
think that having enough information removes the probability. If I
know the exact speed(s), air currents and form of the die and the
table, I could (in theory) predict exactly on which side it would
land.
So the classical world ('real world',
'everyday world') probabilities are really hidden variables.
Stuff we don't know. Probability is in the map and not in theterritory.
How does this differ from Q.M.? Let us
give a parallel.
Say you have a perfectly gray cat.
Perfect in the sense that it is exactly halfway between white and
black on your gray-scale. If you ask 'is the cat gray?' what happens?
The answer is 'yes', and, of course, the cat doesn't care. If you ask
'is the cat black' what happens? You get the answer 'sort of' or
'halfway black', and, again, the cat doesn't care.
Let us assume this cat is an electron,
and color is some property of that electron. The cat is still
perfectly gray. If you ask 'is the cat gray?' what happens? Well, the
answer is 'yes' and the cat doesn't care. It's the same, so no
surprises yet! If you ask 'is the cat black?', two things can happen:
- Answer: 'yes, black' and the cat instantly changes color to black.
- Answer: 'no, not black' and the cat becomes non-black, which, in this case (starting with a grey cat) would actually give you a white cat.
Poor cat. But which of the answers do
you get? If you had 1000 such cats and asked them all, you would get
answer 1) about 500 times, and answer 2) about 500 times, so we say
that the probability of getting 1) is 1/2 and same for 2).
To digress, what Schrødinger's cat is
about (if I understand it correctly), is whether this is actual
probability. Are there any hidden variables determining which of the
cats come out black, or is there an inherent True Probability in
Nature? 'God does not throw dice' -Einstein. If anyone cares, I
believe Einstein to be wrong about this, and that these experimental
outcomes are determined by probability. I also believe the
Schrødinger's cat experiment to be a bad argument, as the cat would
measure whether it was alive or dead. You don't have to be a person
to do an 'experiment', and not a cat either; any two molecules on a
collision course will do an experiment to see whether they collide or
not.
What is special about Q.M. logic? Grey
can be a 'superpositon' of white and black. How do we model this?
There is a certain thing in mathematics called a Hilbert space, where
colors are unit vectors (or subspaces), and a vector [1,1] can be
viewed as a superposition of [1,0] and [0,1].
Why?
Well, experiments show that... But why? This borders on
philosophy. From a scientific point of view, this is our best
model – it works (there's a
friggin' flag on the Moon and a rover on Mars).
No comments:
Post a Comment