– In the 1930s, Albert Einstein was upset
with quantum mechanics. He proposed a thought experiment where, according to the theory,
an event at one point in the universe could instantaneously affect another event arbitrarily
far away. He called this “spooky action at a distance” because he thought it was absurd.
It seemed to imply faster than light communication, something his theory of relativity ruled out.
But nowadays, we can do this experiment, and what we find is, indeed, spooky. But in order
to understand it, we must first understand spin. All fundamental particles have a property
called spin. No, they’re not actually spinning, but the analogy is appropriate. They have
angular momentum, and they have an orientation in space. Now, we can measure the spin of
a particle, but we have to choose the direction in which to measure it, and this measurement
can have only one of two outcomes. Either the particle’s spin is aligned with the
direction of measurement, which we’ll call spin up, or, it is opposite the measurement,
which we’ll call spin down. Now, what happens if the particle spin is vertical, but we measure
it’s spin horizontally? Well then, it has a 50% chance of being spin up, and a 50% chance
of being spin down, and after the measurement, the particle maintains this spin, so measuring
its spin actually changes the spin of the particle. What if we measure spin at an angle
60 degrees from the vertical? Well now, since the spin of the particle is more aligned to
this measurement, it will be spin up 3/4 of the time, and spin down 1/4 of the time. The
probability depends on the square of the cosine of half the angle. Now, an experiment like
the one Einstein proposed can be performed using two of these particles, but they must
be prepared in a particular way. For example, formed spontaneously out of energy. Now, since
the total angular momentum of the universe must stay constant, you know that if one particle
is measured to have spin up, the other, measured in the same direction, must have spin down.
I should point out, it’s only if the two particles are measured in the same direction that their
spins must be opposite. Now here’s where things start to get a little weird. You might imagine
that each particle is created with a definite well-defined spin, but that won’t work, and
here’s why. Imagine their spins were vertical and opposite. Now, if they’re both measured
in a horizontal direction, each one has a 50/50 chance of being spin up. So, there’s
actually a 50% chance that both measurements will yield the same spin outcome, and this
would violate the law of conservation of angular momentum. According to quantum mechanics,
these particles don’t have a well-defined spin at all. They are entangled, which means
their spin is simply opposite that of the other particle. So, when one particle is measured,
and its spin determined, you immediately know what the same measurement of the other particle
will be. This has been rigorously and repeatedly tested experimentally. It doesn’t matter at
which angle the detectors are set, or how far apart they are, they always measure opposite
spins. Now just stop for a minute, and think about how crazy this is. Both particles have
undefined spins, and then you measure one, and immediately you know the spin of the other
particle, which could be light-years away. It’s as though the choice of the first measurement
has influenced the result of the second faster than the speed of light, which is, indeed,
how some theorists interpret the result. But not Einstein. Einstein was really bothered
by this. He preferred an alternate explanation, that all along the particles contained hidden
information about which spin they would have if measured in any direction. It’s just that
we didn’t know this information until we measured them. Now, since that information was within
the particles from the moment they formed at the same point in space, no signal would
ever have to travel between the two particles faster than light. Now, for a time, scientists
accepted this view that there were just some things about the particles we couldn’t know
before we measured them. But then along came John Bell with a way to test this idea. This
experiment can determine whether the particles contain hidden information all along, or not,
and this is how it works. There are two spin detectors, each capable of measuring spin
in one of three directions. These measurement directions will be selected randomly, and
independent of each other. Now, pairs of entangled particles will be sent to the two detectors,
and we record whether the measured spins are the same, both up, or both down, or different.
We’ll repeat this procedure over and over, randomly varying those measurement directions,
to find the percentage of the time the two detectors give different results, and this
is the key, because that percentage depends on whether the particles contain hidden information
all along, or if they don’t. Now, to see why this is the case, let’s calculate the expected
frequency of different readings if the particles do contain hidden information. Now, you can
think of this hidden information like a secret plan the particles agree to, and the only
criterion that plan must satisfy is that if the particles are ever measured in the same
direction, they must give opposite spins. So, for example, one plan could be that one
particle will give spin up for every measurement direction, and its pair would give spin down
for every measurement direction. Or another plan, plan two, could be that one particle
could give spin up for the first direction, spin down for the second direction, and spin
up for the third direction, whereas its partner would give spin down for the first direction,
spin up for the second direction, and spin down for the third direction. All other plans
are mathematically equivalent, so we can work out the expected frequency of different results
using these two plans. Here, I’m visually representing the particles by their plans,
their hidden information. With plan one, the results will obviously be different 100% of
the time. It doesn’t matter which measurement directions are selected, but it does for particles
using the second plan. For example, if both detectors measure in the first direction,
particle A gives spin up, while particle B gives spin down. The results are different.
But if instead, detector B measured in the second direction, the result would be spin
up, so the spins are the same. We can continue doing this for all the possible measurement
combinations, and what we find, is the results are different five out of nine times. So,
using the second plan, the results should be different 5/9 of the time, and using the
first plan, the results should be different 100% of the time, so overall, if the particles
contain hidden information, you should see different results more than 5/9 of the time.
So what do we actually see in experiment? Well, the results are different only 50% of
the time. It doesn’t work, so the experiment rules out the idea that all along, these particles
contain hidden information about which spin they will give in the different directions.
So, how does quantum mechanics account for this result? Well, let’s imagine detector
A measures spin in the first direction, and the result is spin up. Now, immediately you
know that the other particle is spin down if measured in the first direction, which
would happen randomly 1/3 of the time. However, if particle B is measured in one of the other
two directions, it makes an angle of 60 degrees with these measurement directions, and recall,
from the beginning of this video, the resulting measurement should be spin up 3/4 of the time.
Since these measurement directions will be randomly selected 2/3 of the time, particle
B will give spin up 2/3 times 3/4 equals half of the time. So both detectors should give
the same results half of the time, and different results half of the time, which is exactly
what we see in the experiment. So quantum mechanics works. But there is debate over
how to interpret these results. Some physicists see them as evidence that there is no hidden
information in quantum particles, and it only makes sense to talk about spins once they’ve
been measured, whereas other physicists believe that entangled particles can signal each other
faster than light to update their hidden information when one is measured. So, does this mean that
we can use entangled particles to communicate faster than light? Well, everyone agrees that
we can’t. And that is because the results that you find at either detector are random.
It doesn’t matter which measurement direction you select, or what’s happening at the other
detector, there’s a 50/50 probability of obtaining spin up or spin down. Only if these observers
later met up and compared notebooks, would they realize that when they selected the same
direction, they always got opposite spins. Both sets of data would be random, just the
opposite random from the other observer. That is, indeed, spooky, but it doesn’t allow for
the communication, the sending of information from one point to another, faster than light,
so it doesn’t violate the theory of relativity. And that, at the very least, would make Einstein
happy.