Is Superdeterminism a Plausible Explanation for Quantum Mechanics?

In summary, this paper claims that QM has a local realist interpretation, which contradicts the results of the double slit experiment.
  • #71
I'm sick of seeing these permanent and stubborn attempts trying to recover the anthropocentric classical determinism and local realism.
 
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  • #72
Aidyan said:
I'm sick of seeing these permanent and stubborn attempts trying to recover the anthropocentric classical determinism and local realism.
It seems that most arguments pretending to recover realism and locality by refuting Bell's theorem fall mainly in two categories:
1_ Those which are simply wrong from a logical and interpretacional point of view
2_ Those resorting to very implausible arguments such as superdermism

But, even worse, know I realize that there are new experiments that were not anticipated by Bell and Einstein that seem to contradict even more strikingly the notions of reality and locality and that can not be treated with the method used by Bell in his 1964 theorem. Am I correct on this? or I misunderstood the meaning of this new experiments that seem to test entangled particles which do not share a common past causal origin which could presumably be represented by a common hidden variable λ.
 
  • #73
facenian said:
It seems that most arguments pretending to recover realism and locality by refuting Bell's theorem fall mainly in two categories:
1_ Those which are simply wrong from a logical and interpretacional point of view
2_ Those resorting to very implausible arguments such as superdermism

Why do you think superdeterminism is implausible? It is quite easy to reject Bell's statistical independence assumption by looking at any classical field theory, like Maxwell's theory or GR or fluid mechanics. Some superdeterministic proposals may be stupid but this does not mean anything for the concept itself.
 
  • #74
It is not that Superdeterminism is "impossible", it is just that, it is so "ad hoc" that it really explains NOTHING (and of course it predicts nothing in general, so, it is mostly useless).

And yes, I know t'Hooft is working on a Superdeterminism model of Physics, but still...
 
  • #75
ueit said:
Why do you think superdeterminism is implausible?
I think the correct word would be "irrelevant". "Whatever happens ... happens" is not a useful statement in science. It maybe a valid logical one, but one that everybody that wants to make science will ignore ... by design.
 
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  • #76
mattt said:
It is not that Superdeterminism is "impossible", it is just that, it is so "ad hoc" that it really explains NOTHING (and of course it predicts nothing in general, so, it is mostly useless).

And yes, I know t'Hooft is working on a Superdeterminism model of Physics, but still...

Actually, superdeterminism is not a theory, it's a feature of a theory. And as far as I know, there is no plausible theory that has that feature.
 
  • #77
mattt said:
It is not that Superdeterminism is "impossible", it is just that, it is so "ad hoc" that it really explains NOTHING (and of course it predicts nothing in general, so, it is mostly useless).
I agree, I feel it is similar to discussing God's existence in scientific terms
 
  • #78
mattt said:
It is not that Superdeterminism is "impossible", it is just that, it is so "ad hoc" that it really explains NOTHING (and of course it predicts nothing in general, so, it is mostly useless).

And yes, I know t'Hooft is working on a Superdeterminism model of Physics, but still...

A minimalist version of superdeterminism only requires a denial of statistical independence assumption between detector settings and the spins of emitted particles. In order for this assumption to fail it is enough to show that some physical states of the detectors are incompatible with some physical states of the particle source. Take any mainstream field theory, like classical EM and write down the states. For this particular example the states will contain position and momenta of all charged particles inside the detectors and source (electrons and nuclei, or quarks if you like) as well as magnetic and electric field vectors. It is obvious that most states will not be compatible (like a net positive charge at detector A and a null electric field at the source) so the statistical independence assumption fails. Can you point out any ad-hoc assumption in the above argument?
 
  • #79
stevendaryl said:
Actually, superdeterminism is not a theory, it's a feature of a theory. And as far as I know, there is no plausible theory that has that feature.

Please see my above post. Pretty much all field theories have that feature ('t Hooft's CA interpretation is an example of a discrete field theory).
 
  • #80
ueit said:
Please see my above post. Pretty much all field theories have that feature ('t Hooft's CA interpretation is an example of a discrete field theory).

No, field theories do not have that feature. Field theories are deterministic, but not superdeterministic.

The distinction is illustrated by an EPR-type experiment. Consider the question of predicting, for an EPR-type experiment, what detector setting Alice is going to choose in the future. If Alice's choice is governed by deterministic physics, then it is predictable given her past lightcone. But I don't have access to her entire past lightcone.

superdeterministic.jpg


This is illustrated by the picture. The red region is Alice's past lightcone. The yellow region is my past lightcone. The orange region is our shared causal past. Alice's choice could depend on anything in the red region or orange region. But if I'm trying to predict Alice's choice, the only information I have is the orange region. So in general, I do not have enough information to predict Alice's choice.

So Alice's choices are not predictable by me, even if they are deterministic.
 

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  • #81
ueit said:
A minimalist version of superdeterminism only requires a denial of statistical independence assumption between detector settings and the spins of emitted particles. In order for this assumption to fail it is enough to show that some physical states of the detectors are incompatible with some physical states of the particle source. Take any mainstream field theory, like classical EM and write down the states. For this particular example the states will contain position and momenta of all charged particles inside the detectors and source (electrons and nuclei, or quarks if you like) as well as magnetic and electric field vectors. It is obvious that most states will not be compatible (like a net positive charge at detector A and a null electric field at the source) so the statistical independence assumption fails. Can you point out any ad-hoc assumption in the above argument?

The problem is about usefulness.

Could you (or anybody else) have predicted (based on a Superdeterminism model) the experimental results in Bell type tests (and infinitely many other possible different tests) if QM didn't exist (had we never discovered QM) ?

I have seen some papers trying to obtain KNOWN experimental results (that QM predicts correctly) based on Superdeterminism models, but every time it is "adapted" to the known result, it is never a prediction, not even a "natural" or "general" model, but it is totally conceived to just match that previous known result and nothing else.
 
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  • #82
stevendaryl said:
I'm not sure who you're talking to, but I disagree with both of these assertions. As I said, superdeterminism is a feature of a theory, it's not a theory. A superdeterministic theory might very well be testable and useful. But we don't currently have an example of one.

I actually don't think that t'Hooft's automata is a definitive example. He hasn't shown that such automata can plausibly reproduce EPR-type experiments.

I was responding to ueit, but now I am interested in your position.

Do you think we are ever going to find a Superdeterministic model that can actually predict, for example, our choices about instrumental settings?

It is not impossible in principle, but I highly doubt it.
 
  • #83
Ummm, some messages have suddenly dissappeared, what happened?
 
  • #84
mattt said:
Ummm, some messages have suddenly dissappeared, what happened?
One post was removed for a rules violation; and then the posts replying to it, including one of yours, were removed because they no longer had any context. You should have received an alert telling you this happened (if you didn't, it's because I accidentally didn't check the box to make that happen, and I apologize).
 
  • #85
Ah, no problem, I was just curious. But...is it allowed here to talk about Superdeterminism anyway?
 
  • #86
mattt said:
Ah, no problem, I was just curious. But...is it allowed here to talk about Superdeterminism anyway?
Yes. That's not a problem.
 
  • #87
mattt said:
I was responding to ueit, but now I am interested in your position.

Do you think we are ever going to find a Superdeterministic model that can actually predict, for example, our choices about instrumental settings?

It is not impossible in principle, but I highly doubt it.

Is there any difference between this superdetermism and the phylosophical doctrine of fatalism or predeterminism? If not I find it hard to discuss these things in scientific terms at least for the moment. May in the future who knows. Not so long ego it was not possible to talk about the origin of the universe in scientific terms.
 
  • #88
mattt said:
I was responding to ueit, but now I am interested in your position.

Do you think we are ever going to find a Superdeterministic model that can actually predict, for example, our choices about instrumental settings?

It is not impossible in principle, but I highly doubt it.

I highly doubt it, as well. But I don't completely dismiss the possibility. The reason I don't is because there is a sense in which superdeterminism is no weirder than the thermodynamic arrow of time. Maybe understanding the latter might change our view of what is plausible or implausible.
 
<h2>1. What is superdeterminism?</h2><p>Superdeterminism is a philosophical interpretation of quantum mechanics that suggests that all events and outcomes in the universe are predetermined and cannot be altered by human actions or choices.</p><h2>2. How does superdeterminism explain quantum mechanics?</h2><p>Superdeterminism proposes that there are hidden variables that determine the outcomes of quantum events, rather than the randomness and uncertainty described by traditional quantum mechanics. These hidden variables are predetermined and cannot be influenced by human actions.</p><h2>3. Is there any evidence for superdeterminism?</h2><p>Currently, there is no scientific evidence to support the theory of superdeterminism. It is a philosophical interpretation of quantum mechanics and has not been proven or disproven by empirical data.</p><h2>4. What are the criticisms of superdeterminism?</h2><p>One major criticism of superdeterminism is that it goes against the principle of free will, as it suggests that all events and outcomes are predetermined and cannot be altered by human choices. Additionally, it has not been able to provide a clear explanation for certain quantum phenomena, such as entanglement.</p><h2>5. Can superdeterminism be tested?</h2><p>As of now, there is no known way to test for superdeterminism. It is a philosophical interpretation of quantum mechanics and does not make any specific predictions that can be tested through experiments. However, some scientists are working on developing experiments that could potentially provide evidence for or against superdeterminism.</p>

1. What is superdeterminism?

Superdeterminism is a philosophical interpretation of quantum mechanics that suggests that all events and outcomes in the universe are predetermined and cannot be altered by human actions or choices.

2. How does superdeterminism explain quantum mechanics?

Superdeterminism proposes that there are hidden variables that determine the outcomes of quantum events, rather than the randomness and uncertainty described by traditional quantum mechanics. These hidden variables are predetermined and cannot be influenced by human actions.

3. Is there any evidence for superdeterminism?

Currently, there is no scientific evidence to support the theory of superdeterminism. It is a philosophical interpretation of quantum mechanics and has not been proven or disproven by empirical data.

4. What are the criticisms of superdeterminism?

One major criticism of superdeterminism is that it goes against the principle of free will, as it suggests that all events and outcomes are predetermined and cannot be altered by human choices. Additionally, it has not been able to provide a clear explanation for certain quantum phenomena, such as entanglement.

5. Can superdeterminism be tested?

As of now, there is no known way to test for superdeterminism. It is a philosophical interpretation of quantum mechanics and does not make any specific predictions that can be tested through experiments. However, some scientists are working on developing experiments that could potentially provide evidence for or against superdeterminism.

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