Is entanglement still considered spooky ?

  • Thread starter Karl Coryat
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In summary, it's still mysterious to some physicists how entanglement can occur between particles that are spatially separated.
  • #36


salvestrom said:
The outcome is not 50/50 regardless of angle. During calibration it is firmly established that at 0° all outcomes are 1 and at 90° all outcomes are 0. At 45° all outcomes are 50/50. At 60° the outcome is 75% 0's and 25% 1's.
For a photon that is polarized in a particular direction, and you send it through a detector oriented at an angle θ, then the probability it will go through the detector is a sinusoidal function of θ. But for an unpolarized photon, the probability that it goes through a detector is always 50-50 regardless of the angle. And the same is true for entangled photons: if you put one of the entangled photons through a detector, no matter what the angle it will have a 50-50 chance of going through. So even though each of the two photons has a 50-50 chance of going through or not, when you look at their results together you find that they are guaranteed to do the same thing, either both going through or both not going through, if they are detected at the same angle.
In a single detector, non-entangled photon experiment the results are sinusoidal.
Again, you're talking about polarized photons, which are irrelevant for this discussion.
At 60° the deviation from the 0° result is 75%. This is the result of a purely localised experiment.
I'm not sure what you mean by the "deviation from the 0° result". Regardless of whether you're dealing with an ordinary unpolarized photon or an entangled photon, the probability that it goes through the detector is 50% regardless of whether the detector is oriented at 0°, at 60°, or any other angle.
Introducing Bob and entangled photons allows us to do something special. We can now know the outcome of two settings for Alice at the same time. Bob can be set to show us what Alice would show at any given angle, such as -30° while Alice can be set to show another set of results at 30°.
This is all true.
This is a 60° split and will show a 75% deviation, exactly as you get in a localisied experiment. There is nothing non-local implied about this relationship.
No, you're talking about polarized photons. The mystery is not just that there is a 75% probability of a mismatch when the detectors are set 60° apart. The mystery is the contradiction between the following three facts:
1. The probability that P(0) is different from P(30) is 25%
2. The probability that P(-30) is different from P(0) is 25%
3. The probability that P(-30) is different from P(30) is 75%

(Of course, you can switch -30,0,30 to 0,30,60 if you want, it doesn't make a difference.)
Alice is effectively showing a deviation from her own potential results, if we could actually record both angles at once purely using her detector.
That's true.
The only spookyness is in the fact both detectors return pricesly the same results at the same angular setting which could potentially be explained at the point of entanglement.
Well, it could have potentially been explained in that way, but I showed the problems with such an explanation.
My argument is solely that non-locality cannot be in inferred because of the 75% deviation over 60°, because that deviation occurs in a purely localisied version of the experiment as well.
But the kind of experiment with a polarized photon you're discussing doesn't have anything to do with the phenomenon of entanglement, where any single photon will have a 50-50 chance but when you compare the results of the two entangled photons you get a sinusoidal effect.
 
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  • #37


Thanks for pursuing this. I'm going to have to investigate more clearly the detector and what it's doing, it seems. Having said that, it still seems clear, at present, that the sinusoidal shows that the quantity of 1's and 0's at any given angle is not always 50/50. I mean quite literally that the outcome is weighted toward one or the other as you turn the detector. But, as I say, I will take a good long look at the setup description again.

Aside from that, your one query was what I meant by "deviation from the 0° result". The 0° result during calibration was entirely 1's. At 60° it's 75% 0's. That's entirely all I'm referring to. The change in the balance of 1 and 0. While mulling over the whole thing, I came to prefer the term deviation between the balance of 1's and 0's rather than error, because the latter implied one of the detectors was somehow 'wrong', as opposed to 'different'.

No photon left behind.
 
  • #38


It's clear now where the confusion has arisen: I was carrying over the calibration description using polarised light and treating the photons in the experiment as polarised. Well, they are, but we don't know in what way til they hit something. I was also treating it as if every single photon had the same polarisation as the previous one. I realize now that during the experiment there are no angles for which all results are 1 or all results are 0.

Although I wish to think on this some more in general, pursuing any arguements of locality or non-locality at this point would require a largely unanswerable philosophical discussion about QM and the real world, I'd say we're done. Thank you again for the help. Zonde, too. /hug

-
Virtual gnomes: they're in your black hole, radiating your energy!
 
  • #39


salvestrom said:
Well, they are, but we don't know in what way til they hit something.
That can't be right for the following reason. The probability that a polarized photon goes through a detector at an angle θ is a sinusoidal function of θ. The probability that an unpolarized photon (or an entangled photon) goes through a detector is 50-50 independent of θ. So even without knowing in advance what angle a photon may be polarized in, we can determine experimentally whether a photon is polarized or not.
Although I wish to think on this some more in general, pursuing any arguements of locality or non-locality at this point would require a largely unanswerable philosophical discussion about QM and the real world, I'd say we're done. Thank you again for the help. Zonde, too. /hug/
I think you'd find it useful to do more research on Bell's theorem. That's what reveals the heart of the nature of quantum entanglement. For a good popular explanation of all this, you can read Quantum Reality by Nick Herbert, or for a more recent book Amir D'Aczel's Entanglement. If you can't get your hands on these, just searching this forum for threads about Bell's theorem would be an excellent first step.
 
  • #40


lugita15 said:
That can't be right for the following reason. The probability that a polarized photon goes through a detector at an angle θ is a sinusoidal function of θ. The probability that an unpolarized photon (or an entangled photon) goes through a detector is 50-50 independent of θ. So even without knowing in advance what angle a photon may be polarized in, we can determine experimentally whether a photon is polarized or not

I made the assumption because I'm under the impression that unpolarised light is due to large numbers of photons with differing angles of oscillation. I've not found anything that explains how a single photon can be unpolarised. Surely every photon has an angle of oscillation? Or am I missing something (again), i.e. that a photons polarisation isn't the same as its angle of oscillation? Help me, Lugita15, you're my only hope!
 
  • #41


salvestrom said:
I made the assumption because I'm under the impression that unpolarised light is due to large numbers of photons with differing angles of oscillation. I've not found anything that explains how a single photon can be unpolarised. Surely every photon has an angle of oscillation? Or am I missing something (again), i.e. that a photons polarisation isn't the same as its angle of oscillation? Help me, Lugita15, you're my only hope!
An unpolarized photon is just a photon which is in a superposition of polarization states. I assume you know how wave functions work: particles usually have a wave function which is a superposition of a bunch of different states, which means that they have probability amplitudes of being measured in anyone of them. In the case of entangled photons, we have a wave function for the whole two-photon system, and this wave function is in a superposition of polarization states.
 
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  • #42


salvestrom said:
Although I wish to think on this some more in general, pursuing any arguements of locality or non-locality at this point would require a largely unanswerable philosophical discussion about QM and the real world, I'd say we're done. Thank you again for the help. Zonde, too.
Actually there is one argument defending local realism that is not philosophical but rather very practical. Argument is about why that theoretical model I gave does not describe real experiments. It says that fair sampling assumption in photon experiments does not hold.
 
  • #43


zonde said:
Actually there is one argument defending local realism that is not philosophical but rather very practical. Argument is about why that theoretical model I gave does not describe real experiments. It says that fair sampling assumption in photon experiments does not hold.
But hasn't the fair sampling loophole been closed by this experiment? I know we haven't succeeded in doing a single Bell test that closes all loopholes, but hasn't each experimental loophole been closed by at least one experiment or the other (other than superdeterminism, which can never be closed by experiment)?
 
  • #44


lugita15 said:
An unpolarized photon is just a photon which is in a superposition of polarization states. I assume you know how wave functions work: particles usually have a wave function which is a superposition of a bunch of different states, which means that they have probability amplitudes of being measured in anyone of them. In the case of entangled photons, we have a wave function for the whole two-photon system, and this wave function is in a superposition of polarization states.
Have to say you are assuming a lot.
Do you know what is "superposition of states" and what is "probability amplitude"?
 
  • #45


zonde said:
Have to say you are assuming a lot.
Do you know what is "superposition of states" and what is "probability amplitude"?
Yes, I do; I've been studying QM and QFT for years. I assume you're asking this because strictly speaking my comment to salvestrom wasn't technically accurate; an unpolarized photon is in a mixed state, not a pure state. I was just simplifying things a bit to key into the important point that a local measurement of an entangled photon always gives a 50-50 result, while the sinusoidal graph shown in Nick Hebert's page comes from comparing the results of both photons. Even if what I said is not technically true of ordinary unpolarized photons, it is true of entangled photons, but explaining that would have muddied the discussion.
 
  • #46


lugita15 said:
But hasn't the fair sampling loophole been closed by this experiment? I know we haven't succeeded in doing a single Bell test that closes all loopholes, but hasn't each experimental loophole been closed by at least one experiment or the other (other than superdeterminism, which can never be closed by experiment)?
Oh, but I said that it does not hold in photon experiments.
Or do you want to argue that we can apply one to one results of ion experiment to photon experiment?

Besides there are nearly 100% efficient photon detectors. So it should be easy to close fair sampling loophole in photon experiment. This would avoid dubious comparison between photon and ion experiments.
 
  • #47


lugita15 said:
Yes, I do; I've been studying QM and QFT for years. I assume you're asking this because strictly speaking my comment to salvestrom wasn't technically accurate; an unpolarized photon is in a mixed state, not a pure state.
No, I was asking this because there is no consensus about what is "superposition of states" and what is "probability amplitude".
 
  • #48


zonde said:
Oh, but I said that it does not hold in photon experiments.
Or do you want to argue that we can apply one to one results of ion experiment to photon experiment?

Besides there are nearly 100% efficient photon detectors. So it should be easy to close fair sampling loophole in photon experiment. This would avoid dubious comparison between photon and ion experiments.
Does the kind of experiment performed make a difference? Isn't the important thing to demonstrate that the local realist cannot hide behind the fair sampling loophole?
 
  • #49


zonde said:
No, I was asking this because there is no consensus about what is "superposition of states" and what is "probability amplitude".

All states at once and the odds?

That's generally what I take them to mean.

I've been poking around at Bell's theorum all day, He may have enjoyed it. I actually have more questions, but it's late. Play nice.
 
  • #50


lugita15 said:
Does the kind of experiment performed make a difference?
Well, if this ion experiment could stand on it's own then of course there is not much difference. But this is not the case. Possibility that Bell inequalities are violated because of measurement cross-talk is not tested in this kind of experiments.

Basically you have to assume that Bell inequality violations appear due to the same (unknown) physical mechanism in ion experiments and photon experiments only then it means something. Obviously it is much more preferable to avoid such assumptions.

lugita15 said:
Isn't the important thing to demonstrate that the local realist cannot hide behind the fair sampling loophole?
Absolutely not. Important thing is to demonstrate that non-local mysticist cannot hide behind the fair sampling assumption. :tongue:


If you will continue this discussion I have to apologize in advance as I won't be responding for couple of weeks. But I can pick it up later.
 
<h2>1. What is entanglement?</h2><p>Entanglement is a phenomenon in quantum mechanics where two or more particles become connected in such a way that the state of one particle affects the state of the other, regardless of the distance between them. This means that the particles are no longer independent and their properties are linked.</p><h2>2. Why is entanglement considered spooky?</h2><p>Entanglement is considered spooky because it violates our classical understanding of the world, where objects exist independently and their properties are determined by their own state. In entanglement, the properties of particles are linked, even if they are separated by large distances, which goes against our classical intuition.</p><h2>3. Is entanglement still considered spooky?</h2><p>Yes, entanglement is still considered spooky because it challenges our understanding of the fundamental principles of physics. Even though scientists have been able to demonstrate and use entanglement in experiments, its underlying mechanisms are still not fully understood.</p><h2>4. Can entanglement be explained by classical physics?</h2><p>No, entanglement cannot be explained by classical physics. It is a phenomenon that is unique to the quantum world and cannot be understood using classical principles. In fact, entanglement is one of the key differences between classical and quantum mechanics.</p><h2>5. How is entanglement used in practical applications?</h2><p>Entanglement has been used in various practical applications, such as quantum cryptography, quantum teleportation, and quantum computing. It has also been used in experiments to test the foundations of quantum mechanics and to study the behavior of quantum systems.</p>

1. What is entanglement?

Entanglement is a phenomenon in quantum mechanics where two or more particles become connected in such a way that the state of one particle affects the state of the other, regardless of the distance between them. This means that the particles are no longer independent and their properties are linked.

2. Why is entanglement considered spooky?

Entanglement is considered spooky because it violates our classical understanding of the world, where objects exist independently and their properties are determined by their own state. In entanglement, the properties of particles are linked, even if they are separated by large distances, which goes against our classical intuition.

3. Is entanglement still considered spooky?

Yes, entanglement is still considered spooky because it challenges our understanding of the fundamental principles of physics. Even though scientists have been able to demonstrate and use entanglement in experiments, its underlying mechanisms are still not fully understood.

4. Can entanglement be explained by classical physics?

No, entanglement cannot be explained by classical physics. It is a phenomenon that is unique to the quantum world and cannot be understood using classical principles. In fact, entanglement is one of the key differences between classical and quantum mechanics.

5. How is entanglement used in practical applications?

Entanglement has been used in various practical applications, such as quantum cryptography, quantum teleportation, and quantum computing. It has also been used in experiments to test the foundations of quantum mechanics and to study the behavior of quantum systems.

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