Q: Exploring Metaphysics and Quantum Mechanics

In summary: I think they had the right basic idea, but even Paul Davies rejects Hameroff and I simply don't understand Penrose's mathematics well enough to judge his theory. Steven Wolfram believes science is heading for a revolution - that we will eventually come to understand that reality is little more than an iterating mathematical structure. I think he's right. If you think of reality as being made of information, then the mind-body problem is half way to being dissolved. I don't think there was any "matter" before consciousness evolved. There was just information, some of which corresponded to what we call the material world. So the world (as it is in itself) is "made of" information. This information
  • #36
Erwins_mat said:
It boils down to a question about science: does it deliver "truth" about "real things" or is it merely a useful set of tools for making predictions about experiences?

It boils down to a question about epistemology. What else could a mind do except model?

Philosophy and maths are both modelling. Consciousness is modelling. As yoda jedi says, dreaming of Platonic truth, the triumph of pure reason, is transcendental foolishness. That dream had its last gasp with Russell and Whitehead. Godel dealt the final blow.

Consciousness is a useful tool (or rather brain process) for making predictions about experience. That is why the best description of life and mind is "anticipatory system".

"Anticipatory Systems; Philosophical, Mathematical, and Methodolical Foundations", Rosen Enterprises; 2003

Science is a formalisation of what minds do - predict and test, then update the model to reduce future prediction error.

http://www.people.vcu.edu/~mikuleck/rsntpe.html

JR: This is one of the more controversial ramifications of your research, isn't it? That physics is a limited science...

RR: That's right. Especially physicists don't like that. But it's unfortunate that most systems are more like organisms than they are like machines-- simple systems.

JR: And the way they are more like organisms is that they are "complex"...

RR: Exactly. They are complex, and as such they have properties with anticipation, they have properties from emergence and many other kinds of similar things arising from their very nature and they cannot be understood comprehensively the way a physicist likes to understand a rock or a grain of sand.
 
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  • #37
apeiron said:
Consciousness is a useful tool (or rather brain process) for making predictions about experience.

To me, this is meaningless gobbledegook.
 
  • #38
Erwins_mat said:
To me, this is meaningless gobbledegook.

Yes, it helps to have studied the subject in question.
 
  • #39
Hello EM,

Just an interjection here concerning the definition of "metaphysics"?!¿

My experience has been that many metaphysicians herald "energy" as the evidence of their topic... yet energy is a physical property. As far as I know metaphysics describes nothing we could ever conceive of since we are physical beings. So, the word metaphysics, to me, means nothing. Is there a way that you can clarify this term for me in your own words?
 
  • #40
apeiron said:
Yes, it helps to have studied the subject in question.

I have, apeiron. That's why I recognise it as meaningless gobbledegook. You are using words to which you have assigned no meaning. The result is nonsense. You are welcome argue from your own authority until the cow's come home.

What did you study? I'm guessing it wasn't philosophy.
 
  • #41
baywax said:
Hello EM,

Just an interjection here concerning the definition of "metaphysics"?!¿

My experience has been that many metaphysicians herald "energy" as the evidence of their topic... yet energy is a physical property. As far as I know metaphysics describes nothing we could ever conceive of since we are physical beings. So, the word metaphysics, to me, means nothing. Is there a way that you can clarify this term for me in your own words?

Hello baywax.

"Metaphysics" is sometimes taken to mean "new-age woo woo" or something similar. It is also the name of a branch of philosophy. "Energy" is a term which predates science, and which has a non-scientific meaning of "the ability of a system to do work." Science adopted the term to mean something very specific in terms of material systems - it became "the ability of a physical system to do work." As used by your average new-age woo-woo, "energy" means more like the original term. Some may mean exactly what physicists mean, in which case they are making incorrect, pseudoscientific statements. I suspect most mean something more like "the ability of a metaphysical system to do work", in which case the claim is not pseudoscientific and not necessarily wrong, although rather unsupported to say the least.

I would define metaphysics as being anything which needs to make a distinction between the world as we observe it and the world as it exists in itself, independent of our observations of it. Physics has no need of this distinction and cannot do anything with it. Metaphysics starts with it, or at least it did after Kant.

Schroedinger's cat is a perfect example. Cats are unambiguously material things, but a combination of the copenhagen interpretation of QM and Schroedinger's thought experiment leads to the cat in the box being a noumenal cat - it is inherently unobservable. It becomes a phenomenal cat when the box is opened. Science can't resolve the status of the cat, because it is, by definition, unobservable.
 
  • #42
Erwins_mat said:
What did you study? I'm guessing it wasn't philosophy.

That was one of the things certainly.
 
  • #43
Erwins_mat said:
Hello baywax.

"Metaphysics" is sometimes taken to mean "new-age woo woo" or something similar. It is also the name of a branch of philosophy. "Energy" is a term which predates science, and which has a non-scientific meaning of "the ability of a system to do work." Science adopted the term to mean something very specific in terms of material systems - it became "the ability of a physical system to do work." As used by your average new-age woo-woo, "energy" means more like the original term. Some may mean exactly what physicists mean, in which case they are making incorrect, pseudoscientific statements. I suspect most mean something more like "the ability of a metaphysical system to do work", in which case the claim is not pseudoscientific and not necessarily wrong, although rather unsupported to say the least.

I would define metaphysics as being anything which needs to make a distinction between the world as we observe it and the world as it exists in itself, independent of our observations of it. Physics has no need of this distinction and cannot do anything with it. Metaphysics starts with it, or at least it did after Kant.

Schroedinger's cat is a perfect example. Cats are unambiguously material things, but a combination of the copenhagen interpretation of QM and Schroedinger's thought experiment leads to the cat in the box being a noumenal cat - it is inherently unobservable. It becomes a phenomenal cat when the box is opened. Science can't resolve the status of the cat, because it is, by definition, unobservable.

Actually, physics does have a need for it. It's pretty much the basis for falsifiability. I suppose that's where metaphysics takes over? The ufalsifiable?
 
  • #44
Pythagorean said:
Actually, physics does have a need for it. It's pretty much the basis for falsifiability. I suppose that's where metaphysics takes over? The ufalsifiable?

It is related to falsifiability, but only indirectly. Popper's conception of science as only dealing with falsifiable claims was in part a response to Hume's problem of induction, which in turn is set up by the non-observability of "reality as it is in itself."

Some metaphysical claims are falsifiable. These are explanations of material phenomena which had been dumped on metaphysics before science got going. So science ended up falsifying the metaphysical explanation that God is required as a designer of living things. But there are two sides to this. The power of science is directly related to its dependence on observation, and this makes it impossible for it to offer explanations involving metaphysics. That which gives power to science also limits it.
 
  • #45
Erwins_mat said:
Hello baywax.

"Metaphysics" is sometimes taken to mean "new-age woo woo" or something similar. It is also the name of a branch of philosophy. "Energy" is a term which predates science, and which has a non-scientific meaning of "the ability of a system to do work." Science adopted the term to mean something very specific in terms of material systems - it became "the ability of a physical system to do work." As used by your average new-age woo-woo, "energy" means more like the original term. Some may mean exactly what physicists mean, in which case they are making incorrect, pseudoscientific statements. I suspect most mean something more like "the ability of a metaphysical system to do work", in which case the claim is not pseudoscientific and not necessarily wrong, although rather unsupported to say the least.

I would define metaphysics as being anything which needs to make a distinction between the world as we observe it and the world as it exists in itself, independent of our observations of it. Physics has no need of this distinction and cannot do anything with it. Metaphysics starts with it, or at least it did after Kant.

Schroedinger's cat is a perfect example. Cats are unambiguously material things, but a combination of the copenhagen interpretation of QM and Schroedinger's thought experiment leads to the cat in the box being a noumenal cat - it is inherently unobservable. It becomes a phenomenal cat when the box is opened. Science can't resolve the status of the cat, because it is, by definition, unobservable.


I'd have to beg to differ with regard to a "noumenal cat" being unobservable. In actuality we do observe the noumenal cat by observing the neuronal activity producing the concept/ via FMRI and other means.

I would define metaphysics as being anything which needs to make a distinction between the world as we observe it and the world as it exists in itself, independent of our observations of it.

Sorry but this sounds as though you're saying metaphysics has developed a way to observe without observing?

My main point is that there is a huge trap when it comes to metaphysics because it is the study of an unobservable phenomenon. Because of this there is no way to verify the claims of authors and professors of the metaphysical ilk. The ruminations and hallucinations of one person can often take on an air of authority concerning the "unphysical" or "beyond" physical and this can wrongly affect large numbers of people.
 
  • #46
baywax said:
I'
Sorry but this sounds as though you're saying metaphysics has developed a way to observe without observing?

I hope not.

My main point is that there is a huge trap when it comes to metaphysics because it is the study of an unobservable phenomenon. Because of this there is no way to verify the claims of authors and professors of the metaphysical ilk. The ruminations and hallucinations of one person can often take on an air of authority concerning the "unphysical" or "beyond" physical and this can wrongly affect large numbers of people.

Wrongly in what way?
 
  • #47
Erwins_mat said:
I hope not.



Wrongly in what way?

Like convincing many to try the (arsenic laced) Koolaid to see what the leader sees. Or, lay in bed and shoot your brains out because a metaphysical being has told us all to hook a ride on a comet.

Etcetera...

Generally I feel the same way about most dogmatic religion. It steers the individual away from a physical reality that ultimately determines their health and welfare.

Furthermore, the fact that the word "energy" was around before it was closely studied and categorized along with many other phenomena... does not make it any more than it is. The word "light" was around long before it was quantified into photons and used to make electricity. But it always had those capabilities and those physical properties that it does today.

Romanticizing the elements does not make them metaphysical or make them the result of a metaphysical "force". One really has to work on faith to imagine something causing the existence of the physical universe other than the physical universe itself. Faith is one way of observing without observing...
 
  • #48
http://en.wikipedia.org/wiki/Interpretation_of_quantum_mechanics#Comparison

The most common interpretations are summarized in the table below. The values shown in the cells of the table are not without controversy, for the precise meanings of some of the concepts involved are unclear and, in fact, are themselves at the center of the controversy surrounding the given interpretation.

No experimental evidence exists that distinguishes among these interpretations. To that extent, the physical theory stands, and is consistent with itself and with reality; difficulties arise only when one attempts to "interpret" the theory. Nevertheless, designing experiments which would test the various interpretations is the subject of active research.

I'm not sure I understand this.

Nearly a century has passed since quantum theory first started getting "interpreted", and we have something like 20 different metaphysical interpretations. There is currently no means of telling them with an empirical test. I don't understand how any empirical test could ever tell us which one is right. How could the MWI ever be falsified?
 
  • #49
Erwins_mat said:
http://en.wikipedia.org/wiki/Interpretation_of_quantum_mechanics#Comparison
Nearly a century has passed since quantum theory first started getting "interpreted", and we have something like 20 different metaphysical interpretations. There is currently no means of telling them with an empirical test. I don't understand how any empirical test could ever tell us which one is right. How could the MWI ever be falsified?
Hello Erwins_mat,

I think that's why we should focus on interpretations that may be tested experimentally. MWI clearly can't be tested experimentally because there'a whole tail which is experimentally unaccessible. There are however models that we could scale up macroscopically and test against quantum predictions. I'm thinking of particle embedding pilot-waves which show quantum behaviour:

  • http://www.physorg.com/news78650511.html" [Broken]
  • http://prl.aps.org/abstract/PRL/v102/i24/e240401" [Broken]

Arjen
 
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  • #50
ArjenDijksman said:
Hello Erwins_mat,

I think that's why we should focus on interpretations that may be tested experimentally. MWI clearly can't be tested experimentally because there'a whole tail which is experimentally unaccessible. There are however models that we could scale up macroscopically and test against quantum predictions. I'm thinking of particle embedding pilot-waves which show quantum behaviour:

  • http://www.physorg.com/news78650511.html" [Broken]
  • http://prl.aps.org/abstract/PRL/v102/i24/e240401" [Broken]

Arjen


Thankyou, I will investigate...
 
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  • #51
ArjenDijksman said:
Hello Erwins_mat,

I think that's why we should focus on interpretations that may be tested experimentally. MWI clearly can't be tested experimentally because there'a whole tail which is experimentally unaccessible. There are however models that we could scale up macroscopically and test against quantum predictions. I'm thinking of particle embedding pilot-waves which show quantum behaviour:

  • http://www.physorg.com/news78650511.html" [Broken]
  • http://prl.aps.org/abstract/PRL/v102/i24/e240401" [Broken]

Arjen

How do either of those links point a way to differentiate different interpretations of QM? I'm not seeing it.
 
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  • #52
Tao-Fu said:
How do either of those links point a way to differentiate different interpretations of QM? I'm not seeing it.

The results of the experiments described at those links simulate quantum tunneling and quantum interference (as well as other features like orbiting particles with discrete orbitals...). They provide a way to investigate pilot-waves at macroscopic level and therefore to test the consistency of different pilot-wave interpretations of QM. As a matter of fact, they teach us that there's a two-way action between the pilot-wave and the particle, which is a feature that one doesn't find in the conventional Bohmian interpretations.
 
  • #53
ArjenDijksman said:
The results of the experiments described at those links simulate quantum tunneling and quantum interference (as well as other features like orbiting particles with discrete orbitals...). They provide a way to investigate pilot-waves at macroscopic level and therefore to test the consistency of different pilot-wave interpretations of QM. As a matter of fact, they teach us that there's a two-way action between the pilot-wave and the particle, which is a feature that one doesn't find in the conventional Bohmian interpretations.

Er.. this is strange.

These experiments merely MIMIC the QM results. They are not QM experiments!

Furthermore, in those experiments, you can DETECT the associated waves that the "walker" is on. Would you like to guess whether we can detect the analogous "associated waves" in the pilot wave formulation?

Zz.
 
  • #54
ZapperZ said:
These experiments merely MIMIC the QM results. They are not QM experiments!
Yes, exactly. That's what I would require for an interpretation: a formulation that reproduces the results of QM experiments.

Furthermore, in those experiments, you can DETECT the associated waves that the "walker" is on. Would you like to guess whether we can detect the analogous "associated waves" in the pilot wave formulation?
One way to detect the associated waves is through investigation of the spots whereto the "walker" is guided. This concurs with the way how de Broglie conceived the pilot wave interpretation.
 
  • #55
ArjenDijksman said:
Yes, exactly. That's what I would require for an interpretation: a formulation that reproduces the results of QM experiments.

So you don't see that the fact that these are not QM experiments make any difference? I can mimic many Standard Model physics using various condensed matter systems. I can even show Higgs-like mechanism! If we use your logic, there is no need to build the LHC to find the Higgs, since we have already seen a resemblance of it elsewhere. Does this makes any sense to you?

One way to detect the associated waves is through investigation of the spots whereto the "walker" is guided. This concurs with the way how de Broglie conceived the pilot wave interpretation.

No, you missed the point. If we can detect the "associated waves" that came with the pilot wave formulation, we won't be having this conversation. Just looking at where the walker is doesn't tell you anything to distinguish between one interpretation versus another. That's why QM interpretation is still a matter of tastes and personal preference!

Zz.
 
  • #56
ArjenDijksman said:
As a matter of fact, they teach us that there's a two-way action between the pilot-wave and the particle, which is a feature that one doesn't find in the conventional Bohmian interpretations.

Thanks for pointing to such an interesting analogue.

Do you see this fitting in also with a transactional interpretation where there is a "both ways" action?

The droplet/walker is a resonance effect of a system. Inject energy at a locale and (over sufficient time) you produce a standing wave that reflects the global boundary conditions (the shape of the containing vessel, the "diffraction grating" on the bottom).

In QM, the interpretive mistake seems to be to try to find some way to preserve strict locality of causality. Point A in spacetime must connect to point B as a simple path in spacetime - and that is all there is.

Non-locality is really about the global scale in the droplet experiment. The fact that it takes "time" for global downward constraint to be expressed, for a pilot wave-like situation to develop.

In the classical analogue, it actually does take time for a standing wave resonance to build. A clock ticks off locally. But in QM, the "when" becomes a global issue. The local ticking clock to measure, say, the exchange of a photon across a space, is what emerges.

At the global level, this is why the action seems as much retrocausal as causal. The wholeness of the standing wave has to emerge along with the wobbly path traced by a droplet, in effect.
 
  • #57
ZapperZ said:
So you don't see that the fact that these are not QM experiments make any difference?
Oh yes, there is a big difference between QM interpretations (a formulation using math, language, analogues, logic...) and the actual QM behavior. Like you stated it, these walker droplet experiments only mimic some aspects of QM experiments.
I can mimic many Standard Model physics using various condensed matter systems. I can even show Higgs-like mechanism! If we use your logic, there is no need to build the LHC to find the Higgs, since we have already seen a resemblance of it elsewhere. Does this makes any sense to you?
I don't understand what you mean by "my logic" because I don't agree with the inferences you make concerning my line of thought. We need the LHC to validate or invalidate our different interpretations. Meanwhile, nothing prevents us from developing these interpretations along different lines.
No, you missed the point. If we can detect the "associated waves" that came with the pilot wave formulation, we won't be having this conversation. Just looking at where the walker is doesn't tell you anything to distinguish between one interpretation versus another. That's why QM interpretation is still a matter of tastes and personal preference!
Yes, I agree. That's why it is also important to discuss interpretations and to approach them in different ways. With regard to pilot wave interpretations, there's a whole aspect that hasn't be discussed in the past 80 what years: their connexion with pilot wave experiments on another scale.

apeiron said:
Thanks for pointing to such an interesting analogue.

Do you see this fitting in also with a transactional interpretation where there is a "both ways" action?
Yes, why not. Any wave interpretation of QM could benefit from our understanding of ordinary wave behavior.
...
At the global level, this is why the action seems as much retrocausal as causal. The wholeness of the standing wave has to emerge along with the wobbly path traced by a droplet, in effect.
I agree. The global scale of quantum interactions is well illustrated by the extended wave of the droplet analogy.
 
  • #58
ArjenDijksman said:
Oh yes, there is a big difference between QM interpretations (a formulation using math, language, analogues, logic...) and the actual QM behavior. Like you stated it, these walker droplet experiments only mimic some aspects of QM experiments.

And I don't see why you are so gung-ho on these experiments. They are not QM experiments. They are classical experiments that HAPPENED to reproduce some aspect of QM observation. What's the big deal?

I don't understand what you mean by "my logic" because I don't agree with the inferences you make concerning my line of thought. We need the LHC to validate or invalidate our different interpretations. Meanwhile, nothing prevents us from developing these interpretations along different lines.

First of all, none of these experiments are validating "interpretations", and certainly NOT the LHC!

Secondly, if your experiment is nothing more than something that mimics something else, you can't directly test that "something else". This is because that something else has a bunch of other effects that your first experiment cannot replicate. And in QM, everything is connected to each other - you simply can't turn something off while testing something else. You can't test superposition without acknowledging (and testing) the fact that you can also detect the presence of superposition via measuring a non-commuting observable! Try using these experiments that you are such a fan of and produce something similar to the coherence gap observed in the Delft/Stony Brook SQUID experiments!

These are NOT QM experiments. Period. You have no ability to construct a Hamiltonian that is identical to a QM Hamiltonian. The starting point is all wrong, and one is only deceiving oneself to think that one can test "interpretations" of QM using these experiments.

Zz.
 
  • #59
ZapperZ said:
These are NOT QM experiments. Period. You have no ability to construct a Hamiltonian that is identical to a QM Hamiltonian. The starting point is all wrong, and one is only deceiving oneself to think that one can test "interpretations" of QM using these experiments.

Zz.

Thanks for the input, Zapperz. This makes more sense to me. From my perspective, as a neo-Kantian of sorts, it looks completely obvious that the metaphysical interpretations of QM are not science and never can be. We are stuck making observations of, and predictions about, the phenomenal, material world. The interpretations of QM are an attempt to link that phenomenal, material world with a noumenal world. For me, that's metaphysics. The position you end up defending isn't based on empirical evidence but on the need for consistency with other non-scientific beliefs such as "I am a conscious observer", "I believe I have free will" or with other principles like the need for parsimony or a desire to defend metaphysical naturalism.
 
  • #60
Erwins_mat said:
Thanks for the input, Zapperz. This makes more sense to me. From my perspective, as a neo-Kantian of sorts, it looks completely obvious that the metaphysical interpretations of QM are not science and never can be. We are stuck making observations of, and predictions about, the phenomenal, material world. The interpretations of QM are an attempt to link that phenomenal, material world with a noumenal world. For me, that's metaphysics. The position you end up defending isn't based on empirical evidence but on the need for consistency with other non-scientific beliefs such as "I am a conscious observer", "I believe I have free will" or with other principles like the need for parsimony or a desire to defend metaphysical naturalism.

This is true. However, having said that, we should also learn a little bit from history. This is because human ingenuity can sometime surprise us, and what we think can't be tested, later on proved to be wrong.

For example, after the EPR paradox was formulated, the argument on whether it is true or not dragged on for years. It was considered to simply be a "philosophical argument", where various camps adopt a certain specific view or interpretation based on a matter of "tastes". This was because at that time, it was difficult to imagine the possibility of testing such non-local effect.

That all changed after Bell proposed a way to make such a test. This is now no longer philosophy, but physics. The validity of the effect is no longer a matter of "tastes". The interpretation of the effect may still be up in the air, but the result isn't.

I'm not saying that we can differentiate between all of these interpretations eventually. That would be an a priori assumption that the current, standard interpretation of QM is incorrect or incomplete, and we have seen many instances where philosophical arguments never get resolved by physics. All I'm pointing out is that there have been instances where human ingenuity have managed to test something where it wasn't thought to be possible before.

Still, I don't think these experiments based on the "walkers" are such tests.

Zz.
 
  • #61
ZapperZ said:
And I don't see why you are so gung-ho on these experiments. They are not QM experiments. They are classical experiments that HAPPENED to reproduce some aspect of QM observation. What's the big deal?
Hmmm... gung-ho? I merely appreciate those experiments as a physicist because they retrieve some QM results which were regarded impossible to obtain with ordinary macroscopic experiments. They complement our understanding of wave particle duality. What's wrong with mentioning them in a thread about scientifically-acceptable interpretations of QM?

Try using these experiments that you are such a fan of and produce something similar to the coherence gap observed in the Delft/Stony Brook SQUID experiments!

These are NOT QM experiments. Period. You have no ability to construct a Hamiltonian that is identical to a QM Hamiltonian. The starting point is all wrong, and one is only deceiving oneself to think that one can test "interpretations" of QM using these experiments.
I think we misunderstand each other. There is a century old history in quantum mechanics with endless discussions, hundreds of thousands of publications, leading us on a path that made us think in terms in which quantum behavior appears counter-intuitive. And here we have an ordinary physics experiment, which any low-budget lab can reproduce and investigate (you only need a frequency generator, a loud speaker, and a vessel of silicon oil), that challenges the counter-intuitive aspect of quantum behavior. This experiment is still in its infancy. There are only a handful of publications on this experiment, each of which points towards new similarities with QM. Are you inferring that with those few publications, we can have a definite opinion about its applicability to QM?
 
  • #62
ZapperZ said:
And I don't see why you are so gung-ho on these experiments. They are not QM experiments. They are classical experiments that HAPPENED to reproduce some aspect of QM observation. What's the big deal?

The argument would seem to be that an interpretation that makes sense in the classical analogue ought to then lend strength to an equivalent interpretation in QM - given nothing better coming along.

Given two intepretations - say decoherence and MWI - I would prefer the one that has the logic shared with some "obvious" classical system over the truly weird one.

Of course, some direct experimental test would be better. But having an accurate classical analogue is not nothing.
 
  • #63
ArjenDijksman said:
Hmmm... gung-ho? I merely appreciate those experiments as a physicist because they retrieve some QM results which were regarded impossible to obtain with ordinary macroscopic experiments. They complement our understanding of wave particle duality. What's wrong with mentioning them in a thread about scientifically-acceptable interpretations of QM?


I think we misunderstand each other. There is a century old history in quantum mechanics with endless discussions, hundreds of thousands of publications, leading us on a path that made us think in terms in which quantum behavior appears counter-intuitive. And here we have an ordinary physics experiment, which any low-budget lab can reproduce and investigate (you only need a frequency generator, a loud speaker, and a vessel of silicon oil), that challenges the counter-intuitive aspect of quantum behavior. This experiment is still in its infancy. There are only a handful of publications on this experiment, each of which points towards new similarities with QM. Are you inferring that with those few publications, we can have a definite opinion about its applicability to QM?

apeiron said:
The argument would seem to be that an interpretation that makes sense in the classical analogue ought to then lend strength to an equivalent interpretation in QM - given nothing better coming along.

Given two intepretations - say decoherence and MWI - I would prefer the one that has the logic shared with some "obvious" classical system over the truly weird one.

Of course, some direct experimental test would be better. But having an accurate classical analogue is not nothing.

Again, as I've illustrated in my previous post on when something that was a "philosophy" migrates into physics and becomes testable, the only convincing way to settle such an issue is via a very clever methodology of measuring, but on the very same system, not on an "analogous" system that exhibit only SOME of the same effect. One cannot solve the issue of superconductivity by simply studying superfludity, even though a very strong argument can be made that they share many of the same physics. The EPR paradox argument was not solved using an "analogous experiment". It was solved by using the actual, same experiment!

It is a major shortcoming to make a comparison between something when the starting point is all wrong. If you are comfortable in "testing" out some of the interpretation of QM using a classical, non-QM, wrong-Hamiltonian phenomenon, then that's something you have to deal with. I'm surprised we don't just stick to ripple tank. After all, that can "reproduce" QM results too, with so much less cost and so more accessible to grade school students!

Zz.
 
  • #64
ZapperZ said:
Again, as I've illustrated in my previous post on when something that was a "philosophy" migrates into physics and becomes testable, the only convincing way to settle such an issue is via a very clever methodology of measuring, but on the very same system, not on an "analogous" system that exhibit only SOME of the same effect.
I agree. Testing analogous systems only helps us to distinguish between general principles that are valid in both systems, and specific ones applicable only to one particular system.

Or as Fritz Zwicky stated it in New Methods of Thought and Procedure (1967):
It helps us to achieve broad vistas and to derive solutions of specific problems more easily by starting from more general ones. What is most important, however, is that bold generalization enormously stimulates the imagination and often yields unexpected results.

This work has not yet fully been achieved for Quantum Mechanics.
 
  • #65
ArjenDijksman said:
I agree. Testing analogous systems only helps us to distinguish between general principles that are valid in both systems, and specific ones applicable only to one particular system.

Or as Fritz Zwicky stated it in New Methods of Thought and Procedure (1967):
It helps us to achieve broad vistas and to derive solutions of specific problems more easily by starting from more general ones. What is most important, however, is that bold generalization enormously stimulates the imagination and often yields unexpected results.

This work has not yet fully been achieved for Quantum Mechanics.

The problem here is that the "generalization" of the two experiments you cited has nothing to do with QM (ref: the Hamiltonian).

If the Hamiltonian of the two system are similar, then I can be persuaded that there's some merit to such study. Again, this is done in condensed matter all the time, where insights into the mathematics used in, say, elementary particles, are actually similar to those used in various condensed matter system. It isn't a coincidence that Peter Higgs got many of his inspiration in arriving at the so-called Higgs mechanism from various broken symmetry principles already established in condensed matter.

So it is not as if I'm not aware of the usefulness of looking at analogous systems. I just don't see these as being the same and how you could do what you wish to accomplish with them.

Zz.
 
  • #66
ZapperZ said:
The problem here is that the "generalization" of the two experiments you cited has nothing to do with QM (ref: the Hamiltonian).

If the Hamiltonian of the two system are similar, then I can be persuaded that there's some merit to such study. Again, this is done in condensed matter all the time, where insights into the mathematics used in, say, elementary particles, are actually similar to those used in various condensed matter system. It isn't a coincidence that Peter Higgs got many of his inspiration in arriving at the so-called Higgs mechanism from various broken symmetry principles already established in condensed matter.

So it is not as if I'm not aware of the usefulness of looking at analogous systems. I just don't see these as being the same and how you could do what you wish to accomplish with them.
I didn't say that the Hamiltonian can be generalized to the wave + droplet experiment. The generalization with QM seems essentially phenomenological: there are similarities, they apply further than what seemed possible 10 years ago, but it's not yet clear to which extent they apply. There's too little theoretical study on it (unlike for your example of condensed matter physics). However your claim that these experiments have nothing to do with QM sounds to me unconvincing, let alone for the way it is presented in the peer-reviewed papers.

All in all, I think that any scientist who's discussing, advocating or rejecting Bohmian pilot wave interpretations with respect to other interpretations, should know how "real-life" pilot waves behave. That's how I see the way QM interpretation can benefit from the droplet-wave experiments. The same when you use condensed matter analogies for particle physics: you need to know how condensed matter electrons, excitons or plasmons behave in order to draw conclusions for high energy particle physics.

Kind regards,

Arjen
 
<h2>1. What is metaphysics?</h2><p>Metaphysics is a branch of philosophy that deals with fundamental questions about reality, existence, and the nature of being. It explores concepts such as time, space, causality, and consciousness.</p><h2>2. What is quantum mechanics?</h2><p>Quantum mechanics is a branch of physics that studies the behavior of matter and energy at the atomic and subatomic levels. It explains how particles such as electrons and photons behave and interact with each other.</p><h2>3. How are metaphysics and quantum mechanics related?</h2><p>Metaphysics and quantum mechanics are related in that both fields deal with fundamental questions about the nature of reality. Some theories in metaphysics, such as the concept of multiple universes, have been influenced by ideas from quantum mechanics.</p><h2>4. What are some key concepts in metaphysics and quantum mechanics?</h2><p>Some key concepts in metaphysics include ontology (the study of being and existence), epistemology (the study of knowledge), and cosmology (the study of the universe as a whole). In quantum mechanics, key concepts include wave-particle duality, superposition, and entanglement.</p><h2>5. What are some practical applications of metaphysics and quantum mechanics?</h2><p>The practical applications of metaphysics and quantum mechanics are vast and diverse. Metaphysics can help us understand the nature of reality and our place in the universe, while quantum mechanics has led to advancements in technology such as computers, lasers, and medical imaging. It also has implications for fields such as cryptography, energy production, and quantum computing.</p>

1. What is metaphysics?

Metaphysics is a branch of philosophy that deals with fundamental questions about reality, existence, and the nature of being. It explores concepts such as time, space, causality, and consciousness.

2. What is quantum mechanics?

Quantum mechanics is a branch of physics that studies the behavior of matter and energy at the atomic and subatomic levels. It explains how particles such as electrons and photons behave and interact with each other.

3. How are metaphysics and quantum mechanics related?

Metaphysics and quantum mechanics are related in that both fields deal with fundamental questions about the nature of reality. Some theories in metaphysics, such as the concept of multiple universes, have been influenced by ideas from quantum mechanics.

4. What are some key concepts in metaphysics and quantum mechanics?

Some key concepts in metaphysics include ontology (the study of being and existence), epistemology (the study of knowledge), and cosmology (the study of the universe as a whole). In quantum mechanics, key concepts include wave-particle duality, superposition, and entanglement.

5. What are some practical applications of metaphysics and quantum mechanics?

The practical applications of metaphysics and quantum mechanics are vast and diverse. Metaphysics can help us understand the nature of reality and our place in the universe, while quantum mechanics has led to advancements in technology such as computers, lasers, and medical imaging. It also has implications for fields such as cryptography, energy production, and quantum computing.

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