What do violations of Bell's inequalities tell us about nature?

In summary: don't imply that nature is nonlocal ... though it's tempting to assume that nature is nonlocal by virtue of the fact that nonlocal hidden variable models of quantum entanglement are viable.

What do observed violation of Bell's inequality tell us about nature?

  • Nature is non-local

    Votes: 10 31.3%
  • Anti-realism (quantum measurement results do not pre-exist)

    Votes: 15 46.9%
  • Other: Superdeterminism, backward causation, many worlds, etc.

    Votes: 7 21.9%

  • Total voters
    32
  • #106
nanosiborg said:
If the locality condition codifies statistical independence in addition to codifying locality, then the question becomes: is the inconsistency between the statistical independence codified by the locality condition and the statistical dependency necessitated by the experimental design significant enough that this inconsistency is the effective cause of the inconsistency between the predictions of models incorporating the locality condition and experimental results?

I think this is a restatement of the detection and fair-selection "loopholes"...?

That doesn't make it ipso facto wrong, just gives us a starting point for considering whether, in any given experiment, the experiment might not completely preclude locality.
 
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  • #107
Nugatory said:
I think this is a restatement of the detection and fair-selection "loopholes"...?
If that's all it is, then I agree with T. Norsen that there's nothing there. But I think it's a different consideration than these loopholes, which have been more or less covered in more recent experiments, haven't they? Anyway, we're assuming that the applicable assumptions in the QM approach regarding the various usual experimental loopholes are correct and adequate so that when all the usual experimental loopholes are covered then the results will still be in agreement with QM predictions.
 
  • #108
nanosiborg said:
The mathematical proof only tells us that the locality condition is incompatible with QM. The possible incompatibility of the suggested extra illicit (and less visible) assumption can only be demonstrated when evaluated in relation to experimental design.

The mathematical proof tells us that the locality condition is incompatible with the *empirical predictions* of QM. QM, the theory, actually plays zero role whatever in Bell's argument. Or put it this way, it plays exactly the same role that the dBB pilot-wave theory plays. Here's what I mean. Bell formulates a careful definition of locality, and shows on its basis that local theories will always make predictions in accord with the inequality. OK, so now experimentalists go and do the tests and they find that the inequality is empirically violated. So locality is refuted. That's it. Now if you want you can also say: the theory called "QM" makes predictions that violate the inequality, which evidently shows that it must be a nonlocal theory and indeed, if you just look at the theory and test it against Bell's definition of locality, indeed, it's nonlocal. And the same is true for the pilot wave theory, the GRW theory, and all other empirically viable extant theories. But the point is that we never had to say anything -- or even *think* about -- any particular candidate theory in the course of proving that nature is nonlocal.


I just left out, "in addition to codifying locality (ie., causal independence)", which I thought was understood. Certainly the locality condition doesn't only codify statistical dependence. Part of what I'm wondering is if it codifies statistical independence. Or, in other words, does the locality condition only codify locality (causal independence)?

Statistical dependence/independence of what? Maybe that's what I'm missing. If what you mean is: statistical in/dependence of the outcomes, A and B, on the two sides, then there's a sense in which Bell's conditions does just assert statistical independence. Many people over the years have rejected Bell's conclusion on the grounds that, they say, it doesn't rule out *nonlocality*, it just rules out *nonlocal correlations* -- and, they say, two distant events can be *correlated* without one of them causally influencing the other. That's of course true, but such people fail to appreciate the special conditions that Bell described (e.g., that we completely specify the goings-on in the past light cone of one of the events, in a region with a certain special relationship to the other distant event, etc.) under which, actually, "statistical dependence" *does* necessarily require nonlocal causation. I always refer such people to Bell's last (and I think on this subject, best) paper, "la nouvelle cuisine", where he takes as an explicit theme the idea of needing to carefully distinguish causal connections from mere statistical correlations. To whatever extent this is what you're thinking, you would probably benefit from reading that paper too.
 
  • #109
Nugatory said:
I think this is a restatement of the detection and fair-selection "loopholes"...?

That's kind of what I was thinking when I suggested earlier that he was doubting the "no conspiracy" assumption. (Although, really, the "no conspiracies" assumption that is used in the proof of the theorem, is not exactly the same thing as the fair-sampling assumption that experimentalists use when they interpret their data as violating the inequality. They're related, though.)
 
  • #110
Maui said:
The point is not why there could potentially be non-locality but why there is locality.
I'm not very knowledgeable about the various quantum theories of gravity but a number of them try to do away with spacetime. And some physicists, like Gisin, who are convinced that violation of Bell's implies that nature is non-local, further argue that nonlocal quantum correlations would appear to emerge, from "outside" space-time:
To put the tension in other words: no story in space-time can tell us how nonlocal correlations happen, hence nonlocal quantum correlations seem to emerge, somehow, from outside space-time.
Quantum nonlocality: How does Nature perform the trick?
http://lanl.arxiv.org/pdf/0912.1475.pdf
If so, whatever causes entanglement does not travel from one place to the other; the category of “place” simply isn't meaningful to it. It might be said to lie *beyond* spacetime. Two particles that are half a world apart are, in some deeper sense, right on top of each other. If some level of reality underlies quantum mechanics, that level must be non-spatial.
How Quantum Entanglement Transcends Space and Time
http://www.fqxi.org/community/forum/topic/994?search=1

But since only entities localized in spacetime can ever be observed, it's not clear if "progress" can be made on this issue which kind of hi-lites Einstein's concerns; nevertheless, I found these 2 questions/problems discussed in the paper below very interesting and would support what you are suggesting:
...we define a theory to be empirically incoherent in case the truth of the theory undermines our empirical justification for believing it to be true. Thus, goes the worry, if a theory rejects the fundamental existence of spacetime, it is threatened with empirical incoherence because it entails that there are, fundamentally, no local beables situated in spacetime; but since any observations are of local beables, doesn't it then follow that none of our supposed observations are anything of the kind? The only escape would be if spacetime were in some way derived or (to use the term in a very general sense, as physicists do) 'emergent' from the theory. But the problem is that without fundamental spacetime, it is very hard to see how familiar space and time and the attendant notion of locality could emerge in some way...at least without some concrete proposals on the table.
Maudlin quoted in that paper also makes this point which the author refers to and ultimately criticizes (e.g. the bolded part) as Maudlin's challenge:
But one might also try instead to derive a physical structure with the form of local beables from a basic ontology that does not postulate them. This would allow the theory to make contact with evidence still at the level of local beables, but would also insist that, at a fundamental level, the local structure is not itself primitive...This approach turns critically on what such a derivation of something isomorphic to local structure would look like, where the derived structure deserves to be regarded as physically salient (rather than merely mathematically definable). Until we know how to identify physically serious derivative structure, it is not clear how to implement this strategy.
Emergent spacetime and Empirical (In)coherence
http://arxiv.org/pdf/1206.6290.pdf
 
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  • #111
Before this thread goes quietly into the night, I would just like to point out one last time that -- despite the fact that "anti-realism" won the poll by a large margin -- not a single person has been willing to answer my challenge. Here it is one last time in case anybody missed it...

Bell's inequality, as everybody knows, is a constraint on the correlations that can be exhibited between the outcomes of spin measurements on pairs of entangled particles, as the alignments of the measuring devices are changed. In principle, to be empirically viable, a theory needs to be able to make the correct predictions for the statistics that will be observed for *all possible* alignments. But for the sake of discussion, let us focus here on a very small and simple subset -- namely, just the case where both Alice and Bob measure the spins of their particles along the z-direction.

Clearly, to be empirically viable, i.e., to be able to make the right predictions for *all possible* measurements, a theory will have to at least make the right predictions for this particular case. As it turns out, experiment tells us that, in this case, there is a perfect (anti-) correlation of outcomes: whenever Alice's particle goes up, Bob's goes down, and vice versa.

So here is the challenge. People who answered "anti-realism" in the poll evidently believe that there exists a theory that is (a) local and (b) non-realist and which is empirically viable. As noted, this theory must surely be able to explain what is empirically observed in the special case of parallel measurements, if it is really empirically viable. So... what theory is this? Explain how the perfectly anti-correlated outcomes (in just this case where Alice and Bob both measure along the z-direction) can be accounted for in a local but non-realistic model.

Or, if you can't do that, please have the dignity to retract your vote. Thank you very much.
 
  • #112
ttn, you make it sound like this is the first time that a classical explanation for a quantum phenomenon appears inadequate and incoherent. Of course, this is not the case - classical intuition is the number one barrier, you could raise the same Newtonian objections towards the uncertainty principle for instance and the people voting anti-realism are merely acknowledging the reality of observations. Quite a number of experiements have been performed that prove that quantum particles do not have fixed properties at all times, as you would expect classically. I do not understand why a quantum physicist would ever go on a rampage about something as undefensible as realism in quantum physics unless he wanted to turn known physics upside-down. Do you?
 
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  • #113
ttn said:
Statistical dependence/independence of what? Maybe that's what I'm missing. If what you mean is: statistical in/dependence of the outcomes, A and B, on the two sides, ...
Yes.

ttn said:
... then there's a sense in which Bell's condition does just assert statistical independence.
Yes, and I think this might be significant for the following reasons.

The only way to make explicit, to codify, the assumption of locality in a model of quantum entanglement is via the formal expression of statistical independence.

Bell inequalities are based on the correlational boundaries imposed by this formal constraint, which means that any and all 'explicitly local' theories of quantum entanglement can't possibly violate a Bell inequality.

Bell tests are designed to produce statistical dependence (via entirely local means), and
a model explicitly based on statistical independence would not be expected to reproduce all the results of experiments based on statistical dependence.

All of this is fine for Bell's main purpose, which was to see if local (hidden variable, but as we've seen HVs are superfluous) theories of quantum entanglement can be compatible with QM. Or, in other words, if QM could be interpreted locally -- and he proved that it can't be.

However, many people want to extend the applicability of Bell's theorem to say that it means that nature is nonlocal. Which means that statistical dependence of the sort designed into Bell tests is impossible in a local universe. But that doesn't seem reasonable to me, so I wondered where it came from.

Those who believe that Bell's theorem proves that nature is nonlocal have assumed that (via codifying locality as statistical independence) in a local universe, we should expect the angular dependence (the correlation observed experimentally) to be bounded such that it can never reproduce the Malus' Law angular dependence that's observed experimentally.

Prior to the adoption of statistical independence as being formally synonymous with the assumption of locality, the Malus' Law angular dependence is what would have been expected from Bell tests. Following the adoption of statistical independence as being formally synonymous with the assumption of locality, and applying this in models of experiments designed to produce statistical dependence via local means, it was expected that the angular dependence produced in Bell tests would not only not be Malus' Law but would in some cases even be linear -- an expectation that runs contradictory to known empirical optics laws.

In considering this, it seemed to me then that the oddity wasn't the angular dependencies produced in Bell tests, but the fact that Bell inequalities are based on angular dependency expectations that have no foundation in physics. In fact, their sole foundation is the application of models based on statistical independence to experiments based on statistical dependence.

So, there seems to me to be a basic problem with extending the meaning of Bell's theorem to encompass nature. What Bell's theorem does, and the only thing it does (as far as I can tell), is definitively rule out local theories of quantum entanglement (a nonetheless monumental result).

And here I'll restate my position regarding bohm2's poll. Violations of Bell inequalities tell us nothing about nature.
 
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  • #114
Maui said:
ttn, you make it sound like this is the first time that a classical explanation for a quantum phenomenon appears inadequate and incoherent. Of course, this is not the case - classical intuition is the number one barrier, you could raise the same Newtonian objections towards the uncertainty principle for instance and the people voting anti-realism are merely acknowledging the reality of observations. Quite a number of experiements have been performed that prove that quantum particles do not have fixed properties at all times, as you would expect classically. I do not understand why a quantum physicist would ever go on a rampage about something as undefensible as realism in quantum physics unless he wanted to turn known physics upside-down. Do you?

Sure, I love turning stuff upside down. But what you say here doesn't seem relevant. The question (that the poll was about) was not: "is realism true?" It was rather "what do violations of Bell inequalities tell us about nature?" So saying that there is all kinds of evidence that realism is not true -- I agree, it isn't, at least with the silly meaning that people give to it here (namely, non-contextual hidden variables) -- is irrelevant. The point is that something *more* than this -- something *much more interesting than this* -- follows from the violations of Bell's inequality, namely: nonlocality.

Also, part of your comments above suggest that you misunderstood the challenge. I never said that people voting (b) should provide a "classical" (also local and non-realist) explanation of the perfect correlations. The explanation can be "quantum" (whatever that means exactly) or whatever flavor you like. It just has to be local.

Surely the reasoning here is clear? If somebody thinks we get to choose whether to reject realism or locality in the face of Bell inequality violations, and opts for rejecting realism, surely they believe that the empirical data can be explained locally. I'm just saying: put up or shut up. Show me a local non-realist way to explain the perfect correlations or retract your false vote. Simple.
 
  • #115
nanosiborg said:
The only way to make explicit, to codify, the assumption of locality in a model of quantum entanglement is via the formal expression of statistical independence.

No, there's a whole heck of a lot more to it than that. You should read "la nouvelle cuisine" or perhaps my paper on Bell's formulation:

http://arxiv.org/abs/0707.0401


Those who believe that Bell's theorem proves that nature is nonlocal have assumed that (via codifying locality as statistical independence) in a local universe, we should expect the angular dependence (the correlation observed experimentally) to be bounded such that it can never reproduce the Malus' Law angular dependence that's observed experimentally.

They've *assumed* that??!? That's the whole content of the theorem!


Prior to the adoption of statistical independence as being formally synonymous with the assumption of locality, the Malus' Law angular dependence is what would have been expected from Bell tests.

I don't see why. Malus' law has nothing to do with it. That law describes the fraction of photons passing through a polarizer at one angle, which then also pass through a subsequent polarizer at a different angle. It's the probability for a single photon to pass one polarizer, given that it's passed another. In the Bell tests there are two particles. Thinking that it's somehow just "obvious" that they should exhibit statistics that have something to do with Malus' law can only be a confusion.



So, there seems to me to be a basic problem with extending the meaning of Bell's theorem to encompass nature. What Bell's theorem does, and the only thing it does (as far as I can tell), is definitively rule out local theories of quantum entanglement (a nonetheless monumental result).

And here I'll restate my position regarding bohm2's poll. Violations of Bell inequalities tell us nothing about nature.

I find this bizarre. If we know that no local theory can be true, then the correct description of nature is nonlocal. If the true theory is a nonlocal theory, then nature is nonlocal. Yes, it's amazing that we can know that the true theory is a nonlocal theory without (yet) knowing what the true theory *is*. But, that is the situation. Saying that, yes, we know the true theory is nonlocal -- but we can't say anything about nature -- that's bizarre.
 
  • #116
Maui said:
I do not understand why a quantum physicist would ever go on a rampage about something as undefensible as realism in quantum physics unless he wanted to turn known physics upside-down.
Maybe I'm misunderstanding but ttn's argument doesn't have much to with realism. As I understand it, his basic argument with respect to violations of Bell's inequalities is the following:
...the role of Bell’s theorem is not to set constraints on how ‘realist’ we are allowed to be about quantum systems but rather, much more interestingly, to characterize a structural property of any theory that aims to cover the domain of validity covered so far by quantum mechanics, namely non-locality. As a consequence, whether a theory aiming to supersede quantum theory will be ‘realist’, ‘non-realist’, ‘half-realist’ or ‘one-third realist’, this will concern the further conceptual and formal resources of that theory and not at all the Bell theorem.
Non-Local Realistic Theories and the Scope of the Bell Theorem
http://arxiv.org/ftp/arxiv/papers/0811/0811.2862.pdf
 
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  • #117
ttn said:
No, there's a whole heck of a lot more to it than that. You should read "la nouvelle cuisine" or perhaps my paper on Bell's formulation:

http://arxiv.org/abs/0707.0401
Yes, lots of details. But, for the argument I'm currently making, that's the essence of it. I will read those papers, thanks. Maybe they'll change my mind.

ttn said:
They've *assumed* that??!? That's the whole content of the theorem!
It's assumed that what explicitly local models predict is what should be expected in a local universe, ignoring the inconsistency of explicitly local models with experimental design, and what prior empirical optical results would lead us to reasonably expect the results of such tests to be.

ttn said:
I don't see why. Malus' law has nothing to do with it. That law describes the fraction of photons passing through a polarizer at one angle, which then also pass through a subsequent polarizer at a different angle. It's the probability for a single photon to pass one polarizer, given that it's passed another. In the Bell tests there are two particles. Thinking that it's somehow just "obvious" that they should exhibit statistics that have something to do with Malus' law can only be a confusion.
Or maybe it's a not so obvious insight. In Bell tests there are streams of photons, paired by time correlation and a relationship that's presumably produced through some common (local) emission process. What's recorded at both ends as rate of coincidental detection might be seen as analogous to the resulting intensity in Malus' Law setups involving crossed polarizers, and the angular dependence or correlation between rate of coincidental detection and θ seen as analogous (in the ideal) to the Malus' Law angular dependence. But, then again, maybe that's not a good analogy. As I said, I'm just exploring alternatives, because the interpretationally based theoretical 'inference' of nonlocality in nature from Bell test results seems to me to be on rather shaky grounds. Yes, the outcome independence of the locality condition seems to be the only way to make an explicitly local model of quantum entanglement, but it doesn't follow from that that nonlocal models of quantum entanglement are true and correct models of deep reality. The assumption that nature is nonlocal isn't a verifiable or falsifiable hypothesis, and, so far in my explorations, there are at least as many reasons to think that nature is exclusively local as there are to think it's nonlocal.

ttn said:
I find this bizarre. If we know that no local theory can be true, then the correct description of nature is nonlocal. If the true theory is a nonlocal theory, then nature is nonlocal. Yes, it's amazing that we can know that the true theory is a nonlocal theory without (yet) knowing what the true theory *is*. But, that is the situation. Saying that, yes, we know the true theory is nonlocal -- but we can't say anything about nature -- that's bizarre.
What we know is that experiments designed to produce statistical dependence can't be viably modeled by explicit statistical independence. We don't know that any theory is a true 'description' of deep reality. Strictly speaking QM is neither a local nor a nonlocal theory. It doesn't model quantum entanglement in terms of statistical independence and the fact that it takes into account the statistical dependency produced by the experimental designs doesn't make it a nonlocal theory, and anyway it's not designed to be a 'description' of what's happening in deep reality. Imho, it's quite bizarre to conjecture that nature is nonlocal from optical Bell test results, ignoring the inconsistency of explicitly local models with experimental design, and what prior empirical optical results would lead (at least some of) us to reasonably expect the results of such tests to be.

It seems we're at an impasse on this, so, for the moment, we can just agree to disagree. Of course I do agree with your opposition to the "2." ('anti-realism) votes and your clarification of the issue and (non)relevancy of 'realism'. I admire your contributions to your field.

I'm willing to conjecture, even bet on, that nothing that applied physics can actually use (ie., no physical faster than light anything) will ever come from the assumption of nonlocality in nature per se. The most parsimonious 'explanation' for this will remain simply that there's no 'nonlocality' in nature.
 
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  • #118
bohm2 said:
Maybe I'm misunderstanding but ttn's argument doesn't have much to with realism. As I understand it, his basic argument with respect to violations of Bell's inequalities is the following:

...the role of Bell’s theorem is not to set constraints on how ‘realist’ we are allowed to be about quantum systems but rather, much more interestingly, to characterize a structural property of any theory that aims to cover the domain of validity covered so far by quantum mechanics, namely non-locality. As a consequence, whether a theory aiming to supersede quantum theory will be ‘realist’, ‘non-realist’, ‘half-realist’ or ‘one-third realist’, this will concern the further conceptual and formal resources of that theory and not at all the Bell theorem.
Bu we already know that non-contextual chairs and table do not exist according to quantum mechanics, so realism as is usually(naively) defined is broken at the level of atoms and electrons. Given that, who needs additional magic like non-locality at all costs and what does explain better? He has no qm explanation for the reality of chairs and tables that matches both the postulates of qm and our experience of them, so adding non-locality brings nothing substantial. Though it seems obvious that if realism fails, so does locality and nonlocality is implied by the consistence of the classical world and in the end both will be found to be incorrect and incompatible with qm.
 
  • #119
nanosiborg said:
It's assumed that what explicitly local models predict is what should be expected in a local universe, ignoring the inconsistency of explicitly local models with experimental design, and what prior empirical optical results would lead us to reasonably expect the results of such tests to be.

This idea that you keep repeating -- that there is some inconsistency between the theorem and the "experimental design" that makes it improper for us to conclude anything from the experiments -- really makes no sense to me. What you're saying strikes me as just like the following silly scenario. Suppose everybody still thought the world was flat, but somebody figured out that if you designed a rocket and flew up to a very great altitude and looked down and took a picture of the earth, you could really see what shape it is. OK, so they decide to build the rocket and perform the experiment, even though everybody expects that, when they get up there, they'll just see the flat Earth stretching off forever in all directions. Then they run the experiment, take the picture, and -- lo and behold! -- it is immediately obvious that, actually, the Earth is round! Everyone is shocked and surprised!

But then nanosiborg comes along and says: not so fast. There is an inconsistency between the assumption that everybody held (namely that the Earth was flat) and the "experimental design" (meaning that the experiment actually shows that the Earth is round). This inconsistency (which I guess is just the fact that there is a conflict between what many people *expected* and what the experiment actually *showed*) means that actually we cannot conclude from the experiment that the Earth is round. The most we can say is that theories according to which the Earth is flat are no longer viable. But this tells us nothing about nature.

Tell me how what you're saying isn't just parallel to that (I think, manifestly absurd) response to the hypothetical scenario.


The assumption that nature is nonlocal isn't a verifiable or falsifiable hypothesis

Hogwash. Aspect's experiment (and other more recent and better versions of the same thing) experimentally prove that nature is nonlocal. They falsify locality.



Strictly speaking QM is neither a local nor a nonlocal theory.

Hogwash. QM is a nonlocal theory, at least by the best definition of locality that we have going -- namely, Bell's as presented in "la nouvelle cuisine". You have a better/different formulation of "locality" to propose? I'm all ears. Or you think there's some flaw in Bell's formulation? I'm all ears.



I'm willing to conjecture, even bet on, that nothing that applied physics can actually use (ie., no physical faster than light anything) will ever come from the assumption of nonlocality in nature per se. The most parsimonious 'explanation' for this will remain simply that there's no 'nonlocality' in nature.

Quantum teleportation?


Anyway, read the papers I mentioned. It's clear (to me at least) that you are clinging to loopholes that don't in fact exist, because you don't yet fully appreciate what Bell did. You need to study his work carefully before you take a strong position on whether he screwed up or not.
 
  • #120
  • #121
Maui said:
... who needs additional magic like non-locality at all costs and what does explain better?

What non-locality explains better is the results of the Aspect (-type) experiments. The data from these experiments cannot be explained by any local theory. That is what Bell proved.

Don't agree? Then please please please address the challenge I keep posting: tell me how to explain even just the one simple subset of the data (namely, that there are perfect correlations when Alice and Bob measure along the same axis)

(You I think mean to be pointing out that we already know that "realism" is false. Presumably you are thinking of the Kochen-Specker and other similar "no-hidden-variable" theorems. I agree. Realism in that sense is already known to be false. But as bohm2 has explained, this is just a red herring here. To say that Bell's theorem does not prove nonlocality because we already know that realism is false, is like saying that the Earth doesn't go around the sun because we already know the Earth is round. It is just a total non-sequitur. It is possible to know more than one thing, so discovering X does not in any way preclude or automatically refute a purported later proof of Y.)

Though it seems obvious that if realism fails, so does locality and nonlocality is implied by the consistence of the classical world and in the end both will be found to be incorrect and incompatible with qm.

So you agree that no local theory is consistent with experimental data? I can't exactly follow the comments here.
 
  • #122
Quantumental said:
ttn: here is the paper by Wallace where he describes some of the ideas regarding ontology: http://arxiv.org/abs/1111.2189

Thanks. I actually just ordered his book and am looking forward to reading it, but I'll check this out too.
 
  • #123
ttn said:
[..] Tell me how what you're saying isn't just parallel to that (I think, manifestly absurd) response to the hypothetical scenario.
Not sure what he means, but it doesn't seem fair to give him/her the disadvantage of the doubt; fair would be to give him/her the advantage of the doubt. For example, it could be more similar to MMX type experiments: contrary to the generalizing nonsense that one sometimes reads about it those merely disproved a specific set of hypotheses that was put to the test.
[..] QM is a nonlocal theory, at least by the best definition of locality that we have going -- namely, Bell's as presented in "la nouvelle cuisine". You have a better/different formulation of "locality" to propose? I'm all ears. Or you think there's some flaw in Bell's formulation? I'm all ears. [..]
See the recent discussion here:
https://www.physicsforums.com/showthread.php?p=4236787
Thus, apparently Bell implied with "realism" that it "is meaningful to assign a property to a system (e.g. the position of an electron) independently of whether the measurement of such property is carried out."
IMHO that fundamentally disagrees with QM while it is not required for the concept of physical reality, as an electron could be extended as a wave without having a precise, single position. That it should have such a position is an unrealistic definition of "realism" as it only corresponds to a specific subset of models of reality.
 
  • #124
See the recent discussion here:
https://www.physicsforums.com/showthread.php?p=4236787
Thus, apparently Bell implied with "realism" that it "is meaningful to assign a property to a system (e.g. the position of an electron) independently of whether the measurement of such property is carried out."
IMHO that fundamentally disagrees with QM while it is not required for the concept of physical reality, as an electron could be extended as a wave without having a precise, single position. That it should have such a position is an unrealistic definition of "realism" as it only corresponds to a specific subset of models of reality.

What part of that thread is supposed to be relevant? I mean, obviously, there are similar issues being discussed, but I don't know what specifically you meant to be pointing to.

I don't understand your sentence starting "Thus, apparently Bell implied..." Who are you quoting there? I'm pretty sure that isn't a statement of Bell's! Indeed, I don't recall Bell ever talking about "realism". The whole idea that "realism" is somehow relevant to Bell's theorem is an invention of the people who haven't actually studied/understood Bell.

I think I agree with your last couple of sentences, but again isn't the point just that "realism" is used to mean a number of rather different things, so people should be careful to define exactly what they mean whenever they use the term? For example, if the goal is to have what is sometimes described as a "realist interpretation of QM" -- that is, some kind of good old-fashioned style physics theory that makes postulates about what kind of stuff exists and how it acts (rather than, e.g., operationalist-style postulates about laboratory procedures) -- then, no doubt, it would be ridiculous to demand from the outset that electrons must have definite sharp positions at all times. Maybe it will turn out that electrons are like little fuzzy clouds, or like groups of ripples on a pond. Such models would be perfectly "realist" in this sense and certainly shouldn't be ruled out a priori at the outset. I think that was your point, and I totally agree.

But I think people who voted for "anti-realism" in the poll did *not* mean that *this* sort of "realism" is refuted by Bell's theorem. They meant instead the idea that there should exist deterministic non-contextual hidden variables for all (?) "observables" recognized by QM. They are correct that this other sort of "realism" is indeed false, but they are wrong to think that this is the lesson of Bell's theorem. We already knew this realism was wrong, from von Neumann, Kochen-Specker, etc. Bell taught something new, something that has nothing to do with realism.

Anybody who disagrees should explain how to account for the perfect correlations in a local but non-realist way. (Everybody knows you can explain the perfect correlations in a local way *with* this deterministic non-contextual HV sense of "realism". But then everybody also knows that you can't explain the *rest* of the QM predictions with that kind of theory. The question is whether the QM predictions can be accounted for by a theory that is local but non-realist. The challenge is to show that such a model can even account for the perfect correlations subset of the QM predictions. No takers so far, unfortunately.)
 
  • #125
ttn said:
QM is a nonlocal theory, at least by the best definition of locality that we have going -- namely, Bell's as presented in "la nouvelle cuisine". You have a better/different formulation of "locality" to propose? I'm all ears. Or you think there's some flaw in Bell's formulation? I'm all ears.

Bell's definition of "locality" just can't be applied to every possible theory of nature, because it assumes that nature can always be described by classical probabilities of the form [itex]p(a,b,\lambda)[/itex], where [itex]\lambda[/itex] are some unknown parameters. This requirement isn't fulfilled in quantum mechanics, so this definition of locality can't be applied to it in the first place. Quantum mechanics neglects the existence of functions [itex]p(a,b,\lambda)[/itex] entirely. It only predicts functions of the type [itex]p(a,b)[/itex]. So it isn't even possible to decide whether QM is Bell-local or not. In other words: Bells definition of locality isn't general enough to cover all possible theories of nature (including QM) and thus isn't a useful criterion to classify theories at all.

A useful criterion to classify "locality" that covers both QM and classical probability theories is this: A theory is local if an event in one region of spacetime can't influence the experimental outcomes of an experiment in a spacelike separeted region.

In that sense, QM predictions can be explained by completely local quantum theories. Of course non-relativistic QM doesn't count, but relativistic theories like Wightman QFT's can explain the predictions. Locality is even an axiom there.

If you worry about the nonlocal correlations of QM, let's make a simple gedankenexperiment:

You have a green ball and a red ball and put them in two identical boxes. You send these boxes to two different people. These people know that you started with a green and a red ball. So the probability to get green/red is 1/2. When person 1 opens his box, he will get a definite result. Let's say he gets red. Then he knows immediately that person 2 has the green ball in his box, even if that box hasn't been opened yet. This is definitely a nonlocal correlation, but nobody would consider this as an action at a distance.

Up to now, this isn't quantum mechanics yet. But let's do the same experiment with qubits instead of bits. Instead of green and red balls, we put particles with spin into these boxes. We create 2 particled with orthogonal spin states, put them in the boxes and repeat the same experiment. Of course we get nonlocal correlations again, because we separated two particles that were created with correlation locally.

So all the weirdness concerning "nonlocality" is gone and what remains is the standard QM weirdness about the existence of superpositions of states.
 
  • #126
ttn said:
What part of that thread is supposed to be relevant? I mean, obviously, there are similar issues being discussed, but I don't know what specifically you meant to be pointing to.

I don't understand your sentence starting "Thus, apparently Bell implied..." Who are you quoting there? [..]
That post (not that thread) refers to the clarification by DrChinese in post #49 there that Bell imposes the requirement to realism of post #48 that was brought up in the discussion and which for your convenience I also cited here. As discussed there, Bell didn't make that sufficiently clear.
Indeed, I don't recall Bell ever talking about "realism". The whole idea that "realism" is somehow relevant to Bell's theorem is an invention of the people who haven't actually studied/understood Bell.
In view of those remarks of yours, DrChinese's clarification there as well as Bell's paper "Bertlmann's socks and the nature of reality" will be interesting for you.
if the goal is to have what is sometimes described as a "realist interpretation of QM" -- that is, some kind of good old-fashioned style physics theory that makes postulates about what kind of stuff exists and how it acts (rather than, e.g., operationalist-style postulates about laboratory procedures) -- then, no doubt, it would be ridiculous to demand from the outset that electrons must have definite sharp positions at all times. Maybe it will turn out that electrons are like little fuzzy clouds, or like groups of ripples on a pond. Such models would be perfectly "realist" in this sense and certainly shouldn't be ruled out a priori at the outset. I think that was your point, and I totally agree.

But I think people who voted for "anti-realism" in the poll did *not* mean that *this* sort of "realism" is refuted by Bell's theorem. They meant instead the idea that there should exist deterministic non-contextual hidden variables for all (?) "observables" recognized by QM. They are correct that this other sort of "realism" is indeed false, but they are wrong to think that this is the lesson of Bell's theorem. We already knew this realism was wrong, from von Neumann, Kochen-Specker, etc. Bell taught something new, something that has nothing to do with realism.
The issue that recently came up in the linked thread is that those two things are perhaps not unrelated; and in the abovementioned discourse Bell himself highlighted that his theorem has much to do with a certain "realism". Even, as it turns out, "counterfactual" realism. I don't know if it makes a difference but for the moment I'm not convinced about anything.
Anybody who disagrees should explain how to account for the perfect correlations in a local but non-realist way. [..]
:bugeye: Suppose I don't know how a TV works but that I can believe that TV could work. Now you say that therefore I should believe that TV cannot work? That doesn't make any sense to me. A puzzle is just a puzzle, not a conclusion.
The question is whether the QM predictions can be accounted for by a theory that is local but non-realist. The challenge is to show that such a model can even account for the perfect correlations subset of the QM predictions. No takers so far, unfortunately.)
Apparently Neumaier is a taker for a realistic explanation that you call "non-realist" (post #53 there), but not yet ready to deliver. I'm an interested onlooker.
 
  • #127
rubi said:
Bell's definition of "locality" just can't be applied to every possible theory of nature, because it assumes that nature can always be described by classical probabilities of the form [itex]p(a,b,\lambda)[/itex], where [itex]\lambda[/itex] are some unknown parameters. This requirement isn't fulfilled in quantum mechanics, so this definition of locality can't be applied to it in the first place. Quantum mechanics neglects the existence of functions [itex]p(a,b,\lambda)[/itex] entirely. It only predicts functions of the type [itex]p(a,b)[/itex]. [..] we put particles with spin into these boxes. We create 2 particled with orthogonal spin states, put them in the boxes and repeat the same experiment. Of course we get nonlocal correlations again, because we separated two particles that were created with correlation locally.

So all the weirdness concerning "nonlocality" is gone and what remains is the standard QM weirdness about the existence of superpositions of states.
We have had earlier discussions about that, related to Jaynes -it sounds as if you are referring to him. However that's a bit too simplistic, as I found out myself when I presented his arguments here (you can search this forum for Jaynes). There could be something to it, perhaps related to unknown possible type of models, but that never came out as far as I am aware of. While technically speaking his argument is correct (IMHO), it doesn't seem to cut wood. If there is something substantial to it, it still has to be presented on this forum.
 
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  • #128
rubi said:
Bell's definition of "locality" just can't be applied to every possible theory of nature, because it assumes that nature can always be described by classical probabilities of the form [itex]p(a,b,\lambda)[/itex], where [itex]\lambda[/itex] are some unknown parameters. This requirement isn't fulfilled in quantum mechanics, so this definition of locality can't be applied to it in the first place.

I think you're just repeating what Bell's theorem proves, which is that the quantum predictions for probabilities can't be reproduced by a "local variables" theory.
 
  • #129
rubi said:
Bell's definition of "locality" just can't be applied to every possible theory of nature, because it assumes that nature can always be described by classical probabilities of the form [itex]p(a,b,\lambda)[/itex], where [itex]\lambda[/itex] are some unknown parameters. This requirement isn't fulfilled in quantum mechanics, so this definition of locality can't be applied to it in the first place. Quantum mechanics neglects the existence of functions [itex]p(a,b,\lambda)[/itex] entirely. It only predicts functions of the type [itex]p(a,b)[/itex]. So it isn't even possible to decide whether QM is Bell-local or not. In other words: Bells definition of locality isn't general enough to cover all possible theories of nature (including QM) and thus isn't a useful criterion to classify theories at all.

You're just factually wrong here. Ordinary QM absolutely does assert probabilities of the form [itex]p(a,b,\lambda)[/itex] -- it's just that "λ", for QM, is nothing but the wave function ψ. You are of course thinking "no, no, λ is supposed to represent a hidden variable, and by definition there are no such things in QM". But you're just mistaken about how Bell's formulation of locality works. There is nothing like an assumption that "λ" must represent some part of a state description that *supplements* the quantum wave function. The "λ" is rather simply meant to denote "whatever some candidate theory says a complete specification of the physical state of the particle pair, prior to measurement, consists of". So, for ordinary QM, λ is just ψ. For the pilot wave theory, λ is the wave function + the particle positions. And so on.

Go read Bell (start with "la nouvelle cuisine") if you don't believe me.


A useful criterion to classify "locality" that covers both QM and classical probability theories is this: A theory is local if an event in one region of spacetime can't influence the experimental outcomes of an experiment in a spacelike separeted region.

I agree, that's a nice formulation. But how exactly do you translate it into a sharp mathematical statement? How exactly do we decide what it means for one event to "influence" another? What exactly do/should we mean by influencing the "outcomes" -- does this mean only the *statistics* of outcomes, or does it mean the outcomes (or their probabilities) for an actual individual case, or what? The point is: Bell has already worried about these issues and answered these questions! His formulation of locality (in "la nouvelle cuisine") is precisely the needed thing -- a sharp mathematical statement of what you formulate here in words.


In that sense, QM predictions can be explained by completely local quantum theories.

Not true. Even in the simple case of Alice and Bob measuring spin/polarization along parallel axes, a=b, QM's account of the empirical correlations is nonlocal: (supposing Alice happens to measure hers first, then) Alice's measurement influences the state of Bob's particle, which in turn affects Bob's outcomes. (Certain outcomes that were possible -- P = 50% -- prior to Alice's measurement, now become impossible -- P=0 -- for example.)



Of course non-relativistic QM doesn't count, but relativistic theories like Wightman QFT's can explain the predictions. Locality is even an axiom there.

The "locality" that is sometimes taken as an axiom in QFT is different from the "locality" that is at issue in Bell's theorem. The former actually just amounts to what is usually called "no signalling" in the Bell literature. But we know (from the concrete example of the dBB pilot-wave theory for example) that theories can be blatantly non-local (in the Bell sense) and yet be perfectly "local" in the no-signalling sense (because the hidden variables aren't accessible or controllable or whatever).


You have a green ball and a red ball and put them in two identical boxes. You send these boxes to two different people. These people know that you started with a green and a red ball. So the probability to get green/red is 1/2. When person 1 opens his box, he will get a definite result. Let's say he gets red. Then he knows immediately that person 2 has the green ball in his box, even if that box hasn't been opened yet. This is definitely a nonlocal correlation, but nobody would consider this as an action at a distance.

I agree, there's no nonlocality there. Incidentally, a good homework problem would be: go study Bell's formulation of "locality" until you can explain precisely how to use Bell's formulation to (correctly!) diagnose this situation as not involving any nonlocality. This is exactly the kind of exercise one must go through to convince oneself that Bell's formulation is a good formulation!


Up to now, this isn't quantum mechanics yet. But let's do the same experiment with qubits instead of bits. Instead of green and red balls, we put particles with spin into these boxes. We create 2 particled with orthogonal spin states, put them in the boxes and repeat the same experiment. Of course we get nonlocal correlations again, because we separated two particles that were created with correlation locally.

So all the weirdness concerning "nonlocality" is gone and what remains is the standard QM weirdness about the existence of superpositions of states.

I certainly agree that this is exactly the right concrete example to be thinking about to make all these issues crystal clear! But I think you aren't yet there, because you haven't yet understood/appreciated Bell's definition of locality. So, seriously, go read Bell's paper. Then you'll see exactly how, actually, in this situation (I assume here you have in mind that the two particles should be in the total spin zero, the "singlet", state) one can see unambiguously that ordinary QM is nonlocal. It comes down to this: even conditionalizing on what ordinary QM says the complete state of the particles prior to measurement is, the probability P that the theory attributes to a certain one of the possible outcomes (say, B) for Bob's measurement *depends* on the outcome of Alice's measurement (A): P(B|a,b,A,λ) is not equal to P(B|a,b,λ) ... even though the event "A" is spacelike separated from "B". So, translating back to ordinary language, we'd say that A is influencing the outcome B (or more precisely, the probability distribution over the possible outcomes, since we are specifically avoiding any assumption of determinism).

Crucial note: what this proves is that *ordinary QM's explanation of the correlations is nonlocal*. This is not the same as saying, for example, that the correlations that occur when a=b prove the real existence (in nature, not just some candidate theory) of nonlocality. Indeed, we know that the perfect correlations for the case a=b *can* be explained locally -- but *supplementing* QM's λ (namely, ψ) with some additional "hidden variables" that pre-determine the outcome. That was pointed out long ago by Einstein. Bell's discovery was that such models cannot account for the more general correlations that occur when a =/= b.
 
  • #130
harrylin said:
That post (not that thread) refers to the clarification by DrChinese in post #49 there that Bell imposes the requirement to realism of post #48 that was brought up in the discussion and which for your convenience I also cited here. As discussed there, Bell didn't make that sufficiently clear.

Thanks for the clarification of what you were pointing to. I am familiar with Dr Chinese' unique interpretation of these sentences from Bell. But actually it is not Bell here who failed to make something clear -- it is rather Dr C who totally misunderstands the issue. There is absolutely no *assumption* of (what Dr C means by) "realism" in Bell's 1964 paper. And Bell makes this even clearer in his many subsequent papers. The relevant money quote here is something I partially quoted earlier in this thread, from the B's sox paper: "It is remarkably difficult to get this point across, that determinism [aka, DrC's "realism"] is not a *presupposition* of the analysis. There is a widespread and erroneous conviction that for Einstein {^10} determinism was always *the* sacred principle. The quotability of his famous 'God does not play dice' has not helped in this respect... [Bell then here gives some quotes from Born which exhibit this "erroneous conviction". He then continues:] Misunderstanding could hardly be more complete. Einstein had no difficulty accepting that affairs in different places could be correlated. What he could not accept was that an intervention at one place could *influence*, immediately, affairs at another."

And pay special attention to the footnote {^10}: "And his followers. [i.e., Bell is describing himself, as one of Einstein's followers.] My own first paper on this subject (Physics 1, 195 (1965)) starts with a summary of the EPR argument *from locality to* deterministic hidden variables. But the commentators have almost universally reported that it begins with deterministic hidden variables."

And that is precisely the error made by everybody who voted for "anti-realism" in the poll here. They simply *miss* that the argument begins with the EPR argument *from locality to* "realism". They look only at the *second* part of the argument, which shows that "realism" + locality implies a contradiction with experiment. So they *mistakenly* think that we get to choose which of "realism" or locality to reject, in order to avoid the conflict. But in fact there is no such choice. Locality already entails "realism". So to have to choose one to reject is to have to choose locality.


In view of those remarks of yours, DrChinese's clarification there as well as Bell's paper "Bertlmann's socks and the nature of reality" will be interesting for you.

I think the sock is actually on the other foot.


The issue that recently came up in the linked thread is that those two things are perhaps not unrelated; and in the abovementioned discourse Bell himself highlighted that his theorem has much to do with a certain "realism". Even, as it turns out, "counterfactual" realism. I don't know if it makes a difference but for the moment I'm not convinced about anything.

Fair enough. Hopefully the passage I quoted above will encourage everybody to go back and revisit this indeed excellent paper of Bell's. Here is another good passage from it which stresses *exactly* the relevant point here:

"Let us summarize once again the logic that leads to the impasse [i.e., the conclusion of nonlocality]. The EPRB correlations are such that the result of the experiment on one side immediately foretells that on the other, whenever the analyzers happen to be parallel. If we do not accept the intervention on one side as a causal influence on the other, we seem obliged to admit that the results on both sides are determined in advance anyway, independently of the intervention on the other side, by signals from the source and by the local magnet setting. [That was his recapitulation of the EPR argument. Now he turns to the second part of the 2-part argument, the part that is often misleadingly called "Bell's theorem".] But this has implications for non-parallel settings which conflict with those of quantum mechanics. So we *cannot* dismiss intervention on one side as a causal influence on the other."


Apparently Neumaier is a taker for a realistic explanation that you call "non-realist" (post #53 there), but not yet ready to deliver. I'm an interested onlooker.

Me too!
 
  • #131
ttn said:
Not true. Even in the simple case of Alice and Bob measuring spin/polarization along parallel axes, a=b, QM's account of the empirical correlations is nonlocal: (supposing Alice happens to measure hers first, then) Alice's measurement influences the state of Bob's particle, which in turn affects Bob's outcomes. (Certain outcomes that were possible -- P = 50% -- prior to Alice's measurement, now become impossible -- P=0 -- for example.)

I don't think that you can prove that Alice's measurement influences Bob. In ordinary probability theory, someone puts a ball into either Bob's box, or Alice's box, but you don't know which. When Alice opens her box, the probability of Bob finding the ball either drops from 50% to 0%, or rises from 50% to 100%. Does that mean that Alice influenced Bob's box? No, because probabilities are not treated realistically--they are interpreted as reflecting lack of information, or something, rather than something objective about the world.

If you interpret probabilities realistically, then quantum mechanics is nonlocal, but so is classical probability theory. So that's too loose a notion of "nolocal".


The "locality" that is sometimes taken as an axiom in QFT is different from the "locality" that is at issue in Bell's theorem. The former actually just amounts to what is usually called "no signalling" in the Bell literature. But we know (from the concrete example of the dBB pilot-wave theory for example) that theories can be blatantly non-local (in the Bell sense) and yet be perfectly "local" in the no-signalling sense (because the hidden variables aren't accessible or controllable or whatever).

I think that the "no signalling" criterion is the most objective way to define locality. In a Bohm-type theory, there ARE nonlocal interactions, which through a conspiracy manage to be undetectable and unusable for FTL signalling. That's sort of like the case with certain sophisticated aether models for electromagnetic interactions. In these models, there is an absolute rest frame, but things conspire to make it impossible to detect this frame.

I think that both an aether model and a Bohm model are aesthetically unappealing, in exactly the same way:they introduce things into the ontology (absolute rest frame, faster-than-light interactions), and then introduce laws of physics that make these things unobservable. That seems like an unnecessary complication---if there is an element of the model that is unobservable, then it seems better to leave it out, if at all possible.
 
  • #132
ttn said:
You're just factually wrong here. Ordinary QM absolutely does assert probabilities of the form [itex]p(a,b,\lambda)[/itex] -- it's just that "λ", for QM, is nothing but the wave function ψ.

I agree that if there were probabilities of the form [itex]p(a,b,\lambda)[/itex], then for QM, [itex]\lambda[/itex] would have to be the wave function. However, the space of wave functions is too big to be a probability space in the sense of probability theory. In more rigorous terms, this means that no one has succeeded in specifying a sigma-algebra and a probabilty measure on sufficiently big spaces of wave-functions (like the spaces used in QM, for example L^2(R) or Fock spaces). Thus your [itex]p(a,b,\psi)[/itex]'s can't be probabilities and thus my claim still holds: This definition of locality can't be applied to QM.

I agree, that's a nice formulation. But how exactly do you translate it into a sharp mathematical statement?
You can't make a general formal definition, because different theories have different frameworks that work differently. There is no definition that can cover all possible theories (at least i don't know one). You have to look at your given theory and make up a definition for locality that ensures that your intuitive understanding is fulfilled. In Wightman QFT for example, you postulate that commutators of spacelike separated obervables vanish.

Not true. Even in the simple case of Alice and Bob measuring spin/polarization along parallel axes, a=b, QM's account of the empirical correlations is nonlocal: (supposing Alice happens to measure hers first, then) Alice's measurement influences the state of Bob's particle, which in turn affects Bob's outcomes. (Certain outcomes that were possible -- P = 50% -- prior to Alice's measurement, now become impossible -- P=0 -- for example.)
But if that experiment is performed a hundred times, Bob gets a completely consistent probability distribution that he would also calculate if his particle wouldn't be entangled with Alice's particle.

To make the point more clear: Let's assume every particle of the Earth were entangled with some particle in the andromeda galaxy. Is there a way to find out without traveling to andromeda?
 
  • #133
harrylin said:
We have had earlier discussions about that, related to Jaynes -it sounds as if you are referring to him. However that's a bit too simplistic, as I found out myself when I presented his arguments here (you can search this forum for Jaynes). There could be something to it, perhaps related to unknown possible type of models, but that never came out as far as I am aware of. While technically speaking his argument is correct (IMHO), it doesn't seem to cut wood. If there is something substantial to it, it still has to be presented on this forum.

I'm not referring to Jaynes. I've searched the forums, but unfortunately i there's too much results for me to look through. Can you point me to the thread you are referring to?

Maybe i need to point out that i don't object Bell's or CHSH's (and so on) theorems. They're completely valid.
 
  • #134
stevendaryl said:
I don't think that you can prove that Alice's measurement influences Bob. In ordinary probability theory, someone puts a ball into either Bob's box, or Alice's box, but you don't know which. When Alice opens her box, the probability of Bob finding the ball either drops from 50% to 0%, or rises from 50% to 100%. Does that mean that Alice influenced Bob's box? No, because probabilities are not treated realistically--they are interpreted as reflecting lack of information, or something, rather than something objective about the world.

Well, I agree (and indeed wrote!) that (again, considering the simple case where a=b) you cannot prove that Alice's measurement influences Bob. There are local ways to explain these perfectly correlations! And there are nonlocal ways to explain them! Who knows which is right. But the point is, Bell's definition of locality gives us a way to assess whether a *particular candidate theory* (say, ordinary QM, or the pilot wave theory, or some "local realist" theory, ...) provides a local explanation or not. So your response above, while sensible, is actually a response to an assertion that wasn't made. The specific assertion was that *ordinary QM's account, for the perfect a=b correlations, is nonlocal*. Yes, this does not preclude the existence of different theories perhaps explaining those same correlations in a local way. And so it doesn't prove that nonlocality is required to explain them. But just because some *other* theory can explain those particular correlations locally, doesn't mean ordinary QM does! It doesn't!

But again, the lesson here is that if you are slightly confused about all this stuff, then it just means there is a really important and cool thing out there -- namely Bell's formulation of locality -- that you haven't appreciated yet. So go read his paper, or mine, or something.


If you interpret probabilities realistically, then quantum mechanics is nonlocal, but so is classical probability theory. So that's too loose a notion of "nolocal".

Neither Bell or I holds the notion of locality you have in mind here.


I think that the "no signalling" criterion is the most objective way to define locality. In a Bohm-type theory, there ARE nonlocal interactions, which through a conspiracy manage to be undetectable and unusable for FTL signalling.

Now that's an interesting set of statements! So, you agree that, for whatever reason, the Bohm theory precludes signalling (i.e., basically, it agrees with the empirical predictions of QM, including that Bob's marginal shouldn't be affected by Alice's setting). And you want "locality" to just *mean* this no-signalling condition. But then... what in the world do you mean when you say that, despite the no signalling, there ARE nonlocal interactions in the Bohm theory? I actually agree with you that there are, and that this is somehow so obvious that nobody who knew what they were talking about could disagree with it. But didn't you just say there is no objective meaning to "locality" other than the no-signalling business? So, seriously, what do you mean when you say that Bohm's theory is obviously nonlocal? Or is it that we should define locality one way when we're looking at Bohm's theory (you know, to make sure we come to the right conclusion, namely, that Bohm's theory is nonlocal) but then define locality a different way when we turn to look at ordinary QM (you know, to make sure we come to the right conclusion, namely, that ordinary QM is local)?



That's sort of like the case with certain sophisticated aether models for electromagnetic interactions. In these models, there is an absolute rest frame, but things conspire to make it impossible to detect this frame.

I agree, there's some similarity there. Although, incidentally, no sophistication is required. If you literally just take Maxwell's equations, assert that there is some one privileged rest frame in which those equations are true, and then explore the consequences of that theory, you will find that already (without any sophisticated or ad hoc additions or corrections) the theory "conspires" to make it impossible to detect which frame is the privileged one. (Bell wrote a nice paper about essentially this point: "how to teach special relativity.")


I think that both an aether model and a Bohm model are aesthetically unappealing, in exactly the same way:they introduce things into the ontology (absolute rest frame, faster-than-light interactions), and then introduce laws of physics that make these things unobservable. That seems like an unnecessary complication---if there is an element of the model that is unobservable, then it seems better to leave it out, if at all possible.

I don't really disagree. But if we're going to be consistent, then we should also diagnose ordinary QM as "aesthetically unappealing" since the wave function is unobservable, and since any rigorous formulation of it requires one to posit an unobservable absolute rest frame (for wave function collapse to happen instantaneously in).

But really this kind of thing should be a discussion for a different day/thread. The important point here is that ordinary QM -- whether one finds it aesthetically appealing or unappealing -- is a nonlocal theory, and so hardly a counter-example to the claim that only nonlocal theories can make the empirically correct predictions. Maybe for now we can just agree to the following: deciding *which* non-local theory provides the best explanation of the correlations is very difficult, depending as it does on squishy things like aesthetic judgments, and indeed perhaps none of the extant options is fully satisfying.
 
  • #135
ttn said:
Well, I agree (and indeed wrote!) that (again, considering the simple case where a=b) you cannot prove that Alice's measurement influences Bob. There are local ways to explain these perfectly correlations! And there are nonlocal ways to explain them! Who knows which is right. But the point is, Bell's definition of locality gives us a way to assess whether a *particular candidate theory* (say, ordinary QM, or the pilot wave theory, or some "local realist" theory, ...) provides a local explanation or not.

Okay, so you're saying that "there is no local explanation" does not imply "nonlocal"?
 
  • #136
rubi said:
I agree that if there were probabilities of the form [itex]p(a,b,\lambda)[/itex], then for QM, [itex]\lambda[/itex] would have to be the wave function. However, the space of wave functions is too big to be a probability space in the sense of probability theory. In more rigorous terms, this means that no one has succeeded in specifying a sigma-algebra and a probabilty measure on sufficiently big spaces of wave-functions (like the spaces used in QM, for example L^2(R) or Fock spaces). Thus your [itex]p(a,b,\psi)[/itex]'s can't be probabilities and thus my claim still holds: This definition of locality can't be applied to QM.

That's got to be the strangest argument (for the inapplicability of Bell's formulation of locality to ordinary QM) that I've ever heard. Suffice it to say I disagree. Yes, there are lots and lots of different possible ψs. But I don't think there is any technical problem with this of anything like the sort you suggest here. But rather than get into the details of that, just think about how silly this is. If the space of λs is too big for QM, then surely it's too big for Bohm's theory as well, since the physical states in Bohm's theory include everything they include in QM, plus more stuff. Indeed, each particular ψ corresponds to just one possible physical state in QM, whereas it corresponds to an infinite number of possible physical states in Bohm's theory (since there are an infinite number of different ways the particles could be arranged for that ψ)! So evidently you also think that it is impossible to say whether Bohm's theory is local or not? (I consider that a reductio of your argument.)

You can't make a general formal definition, because different theories have different frameworks that work differently. There is no definition that can cover all possible theories (at least i don't know one).

I'd be interested to talk again after you've actually read about Bell's formulation. It is (roughly) an attempt to do what you say here is impossible. So, look at the attempt, and then tell me how exactly you think it goes wrong. Otherwise it's rather like standing in front of the elephant in the room, with your back to it, explaining how there clearly couldn't possibly be an elephant in the room.


You have to look at your given theory and make up a definition for locality that ensures that your intuitive understanding is fulfilled. In Wightman QFT for example, you postulate that commutators of spacelike separated obervables vanish.

I do agree, actually, that Bell's formulation breaks down for certain "exotic" sorts of theories. But nothing as simple as what you have in mind here. See my paper on "Bell's concept of local causality", which discusses at the end some of the exotic sorts of theories where Bell's formulation starts to run into difficulties.


But if that experiment is performed a hundred times, Bob gets a completely consistent probability distribution that he would also calculate if his particle wouldn't be entangled with Alice's particle.

Correct. In other words, Alice can't send a message to Bob this way. Nevertheless, ordinary QM's explanation of the correlations involves nonlocality.


To make the point more clear: Let's assume every particle of the Earth were entangled with some particle in the andromeda galaxy. Is there a way to find out without traveling to andromeda?

Nope. But nevertheless, according to ordinary QM, if all those particles are entangled in the way you describe, then interventions here can causally influence things going on over there.
 
  • #137
ttn said:
Now that's an interesting set of statements! So, you agree that, for whatever reason, the Bohm theory precludes signalling (i.e., basically, it agrees with the empirical predictions of QM, including that Bob's marginal shouldn't be affected by Alice's setting). And you want "locality" to just *mean* this no-signalling condition. But then... what in the world do you mean when you say that, despite the no signalling, there ARE nonlocal interactions in the Bohm theory?

Nonlocal in my sense is relative to a set of state variables. Quantum mechanics has no nonlocal interactions in terms of macroscopic variables (the locations, velocities and orientations of macroscopic objects, the values of macroscopic fields). But the Bohm model introduces additional variables (the positions of microscopic particles) that are subject to nonlocal interactions. IF there were some way to know the values of these microscopic variables, then you could signal through them.

So Bohm-type models explain macroscopic variables that have no nonlocal interactions in terms of microscopic variables that do.
 
  • #138
ttn said:
This idea ... that there is some inconsistency between the theorem and the "experimental design" that makes it improper for us to conclude anything from the experiments -- really makes no sense to me.
Yes, you've made that clear. I'm curious why you put experimental design in quotes.

[ ... snip silly analogy ... ]

ttn said:
Tell me how what you're saying isn't just parallel to that (I think, manifestly absurd) response to the hypothetical scenario.
That should already be clear to you. But, as you've indicated, it isn't. I don't know how to say it any clearer. This isn't your fault. I accept the responsibility for effectively communicating the ideas I'm exploring.

ttn said:
Aspect's experiment (and other more recent and better versions of the same thing) experimentally prove that nature is nonlocal. They falsify locality.
They falsify local theories of quantum entanglement based on Bell's locality condition. They don't prove that nature is nonlocal.

ttn said:
QM is a nonlocal theory, at least by the best definition of locality that we have going -- namely, Bell's as presented in "la nouvelle cuisine". You have a better/different formulation of "locality" to propose? I'm all ears. Or you think there's some flaw in Bell's formulation? I'm all ears.
I'm wondering if you've actually read my posts and thought about the ideas (which are not mine by the way). I've said several times that I agree with you that Bell locality is definitively ruled out as a viable option for modeling quantum entanglement, and that I take Bell's formulation as general. Insofar as effectively exploring the suggestion that QM might be supplemented by LHVs so as to make it a more complete theory of physical reality there's nothing wrong with Bell's formulation. It does that and more, ruling out local theories of quantum entanglement whether HV or realistic or nonrealistic orwhatever.

What it doesn't do is prove that nature is nonlocal.

ttn said:
Quantum teleportation?
There's no physical superluminal transmissions involved in quantum teleportation.

ttn said:
It's clear (to me at least) that you are clinging to loopholes that don't in fact exist, because you don't yet fully appreciate what Bell did.
I'm entertaining and exploring some ideas that I find interesting that you say you don't understand or can't make sense of. They're not 'loopholes' in the usual sense of that word, and I'm not "clinging" to them in the perjorative sense that I take you to mean.

Any clinging that's going on would more appropriately be used to characterize your holding on to the notion that Bell has proved that nature is nonlocal, and your repeated insistence that you simply can't understand or make any sense of the ideas being presented.

So, again, can we just agree to disagree for now? This will be my last post in this thread. You're free to have the last word in our discussion, although I don't see why it would be necessary to reiterate what you've already said unless you want to add some more ad hominems or whatever, as I understand that you can't very well argue (or argue very well) against, or agree with, something that you can't make sense of.

And yes, of course I'll read the papers you suggested. Thanks, sincerely.
 
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  • #139
ttn said:
That's got to be the strangest argument (for the inapplicability of Bell's formulation of locality to ordinary QM) that I've ever heard. Suffice it to say I disagree. Yes, there are lots and lots of different possible ψs. But I don't think there is any technical problem with this of anything like the sort you suggest here.

I'm sorry, but then you are wrong. If you think you are right, then here's a challenge for you: Take the space [itex]L^2(\mathbb R)[/itex] and define some arbitrary example of a probability measure (let's call it [itex]\mu[/itex]) on it (you are absolutely free). Give a meaning to probabilities like for example [itex]P(\psi(3) = 5) = \int_{\psi(3)=5}\mathrm d\mu(\psi)[/itex]. I've given you complete freedom here, so if you think that it is possible, this task should be easy. You can provide an arbitary, completely exotic example if you like.

Bell's definition applies only to situations where such a measure is possible. In classical mechanics for example, the space could be [itex]\mathbb R^{6N}[/itex] and the measure could be given by any probability distribution [itex]\rho(x_1,p_1,\ldots,x_{3N},p_{3N})[/itex] for example.

But rather than get into the details of that, just think about how silly this is. If the space of λs is too big for QM, then surely it's too big for Bohm's theory as well, since the physical states in Bohm's theory include everything they include in QM, plus more stuff. Indeed, each particular ψ corresponds to just one possible physical state in QM, whereas it corresponds to an infinite number of possible physical states in Bohm's theory (since there are an infinite number of different ways the particles could be arranged for that ψ)! So evidently you also think that it is impossible to say whether Bohm's theory is local or not? (I consider that a reductio of your argument.)

Bohms theory isn't nonlocal with resprect to Bell's definition (because it can't be applied) but in the sense of whether there is an action at a distance or not.
 
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  • #140
nanosiborg said:
Yes, you've made that clear. I'm curious why you put experimental design in quotes.

Because it seems like what you actually mean is the *results of*, rather than the *design of*, the experiments. But this is just another way of saying I don't understand what you're getting at, and as you suggest below, it is perfectly reasonable to just leave it there for now.


They falsify local theories of quantum entanglement based on Bell's locality condition. They don't prove that nature is nonlocal.

I would put the first sentence this way: they falsify local theories of quantum entanglement, where "local" is defined in the way Bell defined it.

If we agree about that (and I'm honestly not sure), then the second sentence should read: "This *does* prove that nature is nonlocal (with "local" defined in Bell's way)."

I know you said you didn't want to post more, and trust me, I respect and understand that -- but what I was never able to understand was whether you were saying (a) that Bell's def'n of locality was fine, but that there was some subtle logical presupposition in the analysis *other* than Bell's def'n of locality, or (b) that there is some problem/flaw in Bell's def'n. So, maybe that expression of my confusion will help you sort out how to communicate your idea more effectively next time. Or possibly it's just that I'm dense.


I'm wondering if you've actually read my posts and thought about the ideas (which are not mine by the way). I've said several times that I agree with you that Bell locality is definitively ruled out as a viable option for modeling quantum entanglement, and that I take Bell's formulation as general.

Yes, I've read every word. And I've heard you say those things. But then I hear you saying "but..." with the "..." being stuff that, to me, contradicts the above. So I am continuously thinking that either you must not have meant what you said, or I didn't understand it correctly.

There's no physical superluminal transmissions involved in quantum teleportation.

There's no transmission of useable *information*, to be sure. That is, you can't transmit a *message* superluminally this way. But you'd be hard pressed to explain the fact that quantum teleportation is possible, in terms of a local theory.


So, again, can we just agree to disagree for now? This will be my last post in this thread. You're free to have the last word in our discussion, although I don't see why it would be necessary to reiterate what you've already said unless you want to add some more ad hominems or whatever, as I understand that you can't very well argue (or argue very well) against something that you can't make sense of.

Of course. I'm sincerely sorry if my posts have come off as attacking you. That wasn't intended at all. I was just trying (perhaps too hard?) to understand what you were saying. And the reason I kept going back to the general points about Bell's theorem is not that I ignored your statements about where you agreed with me -- rather I was just trying to keep this part of the thread it's embedded in, i.e., connect it back, largely for the purposes of other people who might be reading, to the big issue at hand here, namely, whether Bell's theorem should be understood as refuting "realism" or "locality". Sorry if the attempt to keep both of those balls in the air (talking with you and arguing for a general audience about the main issue of the thread) made it seem like I was throwing balls at you undeservedly.
 
<h2>1. What are Bell's inequalities and how do they relate to nature?</h2><p>Bell's inequalities are a set of mathematical inequalities that describe the limits of classical physics in explaining certain phenomena in nature. They are used to test the validity of quantum mechanics, which is a more accurate and comprehensive theory of nature.</p><h2>2. Why are violations of Bell's inequalities significant?</h2><p>Violations of Bell's inequalities indicate that classical physics is not sufficient to explain certain phenomena in nature, and that quantum mechanics is a more accurate and comprehensive theory. This challenges our understanding of the fundamental laws of nature and opens up new possibilities for scientific exploration.</p><h2>3. How are violations of Bell's inequalities detected?</h2><p>Violations of Bell's inequalities are detected through experiments that involve measuring the properties of entangled particles. These particles are connected in such a way that their properties are correlated, even when they are separated by large distances. By measuring the properties of these particles, scientists can determine if they violate Bell's inequalities.</p><h2>4. What do violations of Bell's inequalities tell us about the nature of reality?</h2><p>Violations of Bell's inequalities suggest that reality is not as deterministic as classical physics suggests. Instead, it supports the idea that quantum mechanics allows for non-local connections between particles, and that the act of measurement can affect the properties of these particles. This challenges our traditional understanding of causality and the nature of reality.</p><h2>5. How do violations of Bell's inequalities impact our understanding of the universe?</h2><p>Violations of Bell's inequalities have significant implications for our understanding of the universe. They suggest that there are fundamental aspects of reality that are beyond our current understanding, and that there may be new laws and principles at work in the universe. This opens up new avenues for research and exploration in the field of quantum mechanics and the nature of the universe.</p>

1. What are Bell's inequalities and how do they relate to nature?

Bell's inequalities are a set of mathematical inequalities that describe the limits of classical physics in explaining certain phenomena in nature. They are used to test the validity of quantum mechanics, which is a more accurate and comprehensive theory of nature.

2. Why are violations of Bell's inequalities significant?

Violations of Bell's inequalities indicate that classical physics is not sufficient to explain certain phenomena in nature, and that quantum mechanics is a more accurate and comprehensive theory. This challenges our understanding of the fundamental laws of nature and opens up new possibilities for scientific exploration.

3. How are violations of Bell's inequalities detected?

Violations of Bell's inequalities are detected through experiments that involve measuring the properties of entangled particles. These particles are connected in such a way that their properties are correlated, even when they are separated by large distances. By measuring the properties of these particles, scientists can determine if they violate Bell's inequalities.

4. What do violations of Bell's inequalities tell us about the nature of reality?

Violations of Bell's inequalities suggest that reality is not as deterministic as classical physics suggests. Instead, it supports the idea that quantum mechanics allows for non-local connections between particles, and that the act of measurement can affect the properties of these particles. This challenges our traditional understanding of causality and the nature of reality.

5. How do violations of Bell's inequalities impact our understanding of the universe?

Violations of Bell's inequalities have significant implications for our understanding of the universe. They suggest that there are fundamental aspects of reality that are beyond our current understanding, and that there may be new laws and principles at work in the universe. This opens up new avenues for research and exploration in the field of quantum mechanics and the nature of the universe.

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