Copenhegen interpretation or Many World Interpretation?

In summary: So the definition of science requires indicator components of measuring devices to be for all practical purposes indistinguishable from classical.In summary, there is no such experiment that could settle the debate between CI and MWI. Scientists today seem to favor MWI, which allows time travel while avoiding the grandfather paradox, but the lack of a quantum theory of gravity makes it uncertain whether such an experiment is even possible.
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Can there be an experiment (even a thought experiment), which could settle the debate CI vs MWI? Now a days many scientists seem to favour MWI. I find it interesting because it perhaps allows time travel (the possibility of an observer going back to his/her own past) while avoiding the grandfather paradox, since, having visited your past, you can come back to a "different present" in a parallel universe. This is what I read in one of the popular science books.
 
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  • #2
No, there's no such experiment.

We would need a quantum theory of gravity before we can even try to make an argument for that time travel thing. So that popular science book is doing some wild speculation.
 
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  • #3
In principle... probably, yes. Every interpretation of a model has implications along with it, and it is just a matter of time before someone clever enough comes along and sees a way to measure the reality of one set of implications verse another.

I am not that someone, however. All I can add is we have no mathematical understanding of the collapse of a probability into a specific outcome, which means if our quantum model reflects "actual reality", then it follows that either our model is incomplete, or else the other information produced by our model (the other outcomes and their probabilities) should also be realized somehow.

The amazing accuracy of quantum predictions is a fair vote in the "actual reality" column, however the failure to accommodate gravity is a contradictory vote in the "incomplete model" column. That is more or less the juncture on which this debate stands.
 
  • #4
Fredrik said:
No, there's no such experiment.

If you mean we don't have the technology for such an experiment, then that's true. If you mean such an experiment is impossible in principle, that's not true. There may or may not be an experiment that will distinguish MWI from other no-collapse interpretations; however, there are theoretically measurable difference between MWI and collapse interpretations like Copenhagen. In particular, measurement is theoretically reversible in MWI while it is not in Copenhagen. Quantum decoherence makes it questionable whether such experiments will ever be possible in practice—but that is different from there being no such experiment, full stop. See here for a more detailed overview.
 
  • #5
LastOneStanding said:
If you mean we don't have the technology for such an experiment, then that's true. If you mean such an experiment is impossible in principle, that's not true.
I mean that it's impossible in principle. It is so by definition of "interpretation". If a statement about the real world has falsifiable consequences, then it's a theory, not an interpretation.

LastOneStanding said:
In particular, measurement is theoretically reversible in MWI while it is not in Copenhagen.
I would say that this is a misunderstanding of the term "Copenhagen". I almost never use that term myself, because you can't find two people who define it the same way. But I have a strong opinion about one aspect of it at least: The idea that measuring devices "are classical" is a serious misunderstanding of Bohr's original idea, which was more along the lines of: Science requires theories to be falsifiable. To be falsifiable, they must make predictions about results of experiments. So the definition of science requires indicator components of measuring devices to be for all practical purposes indistinguishable from classical.

That's how I interpret Bohr anyway. I know that there are lots of people who interpret his statements as saying that the laws of nature are such that measuring devices are fundamentally classical. But I find it very unlikely that Bohr believed anything that silly.

LastOneStanding said:
See here for a more detailed overview.
What am I supposed to do with a dictionary entry on the MWI?
 
  • #6
Fredrik said:
I mean that it's impossible in principle. It is so by definition of "interpretation". If a statement about the real world has falsifiable consequences, then it's a theory, not an interpretation.

Which is why, in many ways, many worlds "interpretation" is a misnomer. The fact that people call it an interpretation doesn't rule out the possibility for experimental tests. This is bizarre, backwards reasoning: I named specific tests for non-collapse QM like MW, and instead of saying, 'If there are tests, we shouldn't call it an interpetation,' you seem to say, 'That can't be right, it's called an interpretation so there are no tests.' Langauge is descriptive, not prescriptive, on reality. Sometimes those descriptions are wrong.

I would say that this is a misunderstanding of the term "Copenhagen". I almost never use that term myself, because you can't find two people who define it the same way. But I have a strong opinion about one aspect of it at least: The idea that measuring devices "are classical" is a serious misunderstanding of Bohr's original idea, which was more along the lines of: Science requires theories to be falsifiable. To be falsifiable, they must make predictions about results of experiments. So the definition of science requires indicator components of measuring devices to be for all practical purposes indistinguishable from classical.

I never said Copenhagen was about measuring devices "being classical", so I have no idea what your objections have to do with anything I've said. Wavefunction collapse is a component of the Copenhagen interpretation (at least, the modern take on it), and is the entire reason the latter has led to the so-called measurement problem. Since collapse is a one-way, non-unitary process, it leads to theoretically distinguishable predictions of collapse vs. no-collapse QM. I have never seen the Copenhagen interpretation not defined with, in part, wavefunction collapse so while you're perfectly entitled to your own private definition, I think it's a very non-standard one and certainly not what the OP had in mind with the question.

What am I supposed to do with a dictionary entry on the MWI?

Since I specifically linked you to a section entitled "Tests of the MWI", I would think "read it" would be a cracking start.
 
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  • #7
LastOneStanding said:
...instead of saying, 'If there are tests, we shouldn't call it an interpetation,' you seem to say, 'That can't be right, it's called an interpretation so there are no tests.'
I'm saying that if it is an interpretation, there are no tests. I don't think I've heard the claim that it's not an interpretation before.

LastOneStanding said:
I never said Copenhagen was about measuring devices "being classical", so I have no idea what your objections have to do with anything I've said.
The idea that wavefunction collapse is a non-unitary physical process that projects the wavefunction exactly onto an eigenstate, is almost certainly based on those misunderstandings of Bohr that I mentioned, not on Bohr's actual beliefs.

Now that we know about decoherence, there's no reason to think that there's such a thing as a non-unitary collapse. The decoherence approach is to apply QM to a larger system that includes an environment. The result is an apparent collapse. Interactions with the environment put the system in a state that's practically indistinguishable from a collapsed state.

This doesn't contradict Copenhagen, because we're just using the same theory (and if we want to, the same interpretation) to a larger system.

LastOneStanding said:
Since I specifically linked you to a section entitled "Tests of the MWI", I would think "read it" would be a cracking start.
I didn't see that you linked to that section. The page is displayed from the top until it has finished loading, and then the browser scrolls down to that section. This takes a couple of seconds. I had already closed the tab before that. I might take a look at it later.
 
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Fredrik said:
I'm saying that if it is an interpretation, there are no tests. This is equivalent to the first statement you made, not the second.

I'm still don't understand why you're so hung up on the word interpretation. Many worlds makes a number of claims. Those claims are testable, in principle. If you think that means it shouldn't be called an interpretation, then it's not an interpretation by your reckoning. The fact that people call it an interpretation does not say whether it may or may not be testable. It just means people might be using an inappropriate word for it.

The idea that wavefunction collapse is a non-unitary physical process that projects the wavefunction exactly onto an eigenstate, is almost certainly based on those misunderstandings of Bohr that I mentioned, not on Bohr's actual beliefs.

Whether it's a historical misunderstanding or not, that is what people currently mean by the term. Between this and the last quote, I think you are getting unnecessarily hung up on language. By "Copenhagen interpretation", it's reasonable to assume the OP meant what nearly everyone mean by the term today. Instead of considering whether it's possible to distinguish between MW and "the usual framework people mean by 'Copenhagen'", you're arguing that the term is inappropriate for the concept. While a perfectly reasonable discussion to have for it's own sake, it's largely irrelevant here. Your focusing on the word and not it's intended referent.

Fine, we won't say the C-word since it bothers you. We'll say that the answer to, "Can Copenhagen and Many Worlds be empirically distinguished?" is "no" on the grounds that "Copenhagen" is not a well-defined model of QM, being subject to disagreement on its definition. Instead, we'll ask, "Can Many Worlds be empirically distinguished from other well-defined models of QM?" The answer to that is yes. MW is empirically distinguishable from (and has been experimentally preferred over some) variants of QM of involving wavefunction collapse. Whether it can be empirically distinguished from other non-collapse variants is not yet clear.

Now that we know about decoherence, there's no reason to think that there's such a thing as a non-unitary collapse. The decoherence approach is to apply QM to a larger system that includes an environment. The result is an apparent collapse. Interactions with the environment put the system in a state that's practically indistinguishable from a collapsed state.

This doesn't contradict Copenhagen, because we're just using the same theory (and if we want to, the same interpretation) to a larger system.

Actually, you just described Many Worlds pretty well, so apparently you don't need empirical convincing of it. All Many Worlds quantum mechanics, at its most basic, consists of is the claim that wavefunctions don't collapse and so the universe's wavefunction stays in an overall superposition. However, for subsystems, quantum decoherence gives the appearance of collapse since entanglement allows individual subsystems entangled with others to follow the statistics of mixtures instead of superpositions. A "world" is just one of the states of a macroscopic system that composes the (incoherent) statistical mixture after quantum decoherence. I've always thought deWitt did Everett a major disservice by branding the latter's theory "Many Worlds", since it seems to conjure up mistaken thoughts of some kind of multiverse for people. All it is, at it's simplest, is quantum mechanics with the collapse postulate removed and no new ones (like Bohm's) to replace it.

If you think this view is compatible with Copenhagen, then I'll reiterate that I think your use of the word is very non-standard. However, the point remains: if we put aside "Copenhagen interpretation" as a not-very-helpful term, then various purported models of quantum mechanics—models that are usually, though perhaps inaccurately, called "interpretations"—may still be experimentally distinguished from one another. Many Worlds—which you are apparently already on board with, even if you haven't realized it—can be distinguished from other mainstream models.

I didn't see that you linked to that section. The page is displayed from the top until it has finished loading, and then the browser scrolls down to that section. This takes a couple of seconds. I had already closed the tab before that. I might take a look at it later.

No worries. I do recommend reading it though, and I hope you aren't put off by the source. I think physicists can often be overly dismissive of the work done by philosophers of physics, who are generally extremely well versed with the formalism and do a lot of things that would probably be better classified as 'physics' than 'philosophy'.
 
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  • #9
Fredrik said:
Now that we know about decoherence, there's no reason to think that there's such a thing as a non-unitary collapse. The decoherence approach is to apply QM to a larger system that includes an environment. The result is an apparent collapse. Interactions with the environment put the system in a state that's practically indistinguishable from a collapsed state.
I guess you will agree to the following remark: decoherence does not cause a collaps to one pure state but only an effective diagonalization of the reduced density matrix (which still dos not correspond to a pure state). So the generalized quantum state "dead and alive" decoheres to "either dead or alive". But for a single cat still both possibilities are contained in the reduced density matrix. So decoherence
a) does explain why we observe a classical state of the cat, but
b) it does not tell us which state (either "dead" or "alive") will be observed.
So - even taking decoherence into account - in some sense there is still a collapse of the density matrix "dead or alive" to one pure state, e.g. "dead".
 
  • #10
tom.stoer said:
I guess you will agree to the following remark: decoherence does not cause a collaps to one pure state but only an effective diagonalization of the reduced density matrix (which still dos not correspond to a pure state). So the generalized quantum state "dead and alive" decoheres to "either dead or alive". But for a single cat still both possibilities are contained in the reduced density matrix. So decoherence
a) does explain why we observe a classical state of the cat, but
b) it does not tell us which state (either "dead" or "alive") will be observed.
So - even taking decoherence into account - in some sense there is still a collapse of the density matrix "dead or alive" to one pure state, e.g. "dead".

Which is why what Fredrik is describing is precisely the Many Worlds interpretation as it's now understood. Without genuine collapse (and thanks to decoherence), the result of me doing a Schrodinger's cat experiment is that the reduced density matrix of the cat and me together (which decoherence has effectively diagonalized) is an incoherent mixture of "cat is dead and I saw a dead cat in the box" and "cat is alive and I saw a live cat in the box". Since in our subsystem that superposition is now incoherent, the two macroscopic pure states in the mixture ("worlds") continue evolving completely independently of each other.
 
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LastOneStanding said:
Without genuine collapse (and thanks to decoherence), the result of me doing a Schrodinger's cat experiment is that the reduced density matrix of the cat and me together (which decoherence has effectively diagonalized) is an incoherent mixture of "cat is dead and I saw a dead cat in the box" and "cat is alive and I saw a live cat in the box".
Yes, this is decoherence as an application of the QM formalism.

LastOneStanding said:
Since in our subsystem that superposition is now incoherent, the two macroscopic pure states in the mixture ("worlds") continue evolving completely independently of each other.
And now we talk about an interpretation. Instead of interpreting the incoherent superposition as independent branches in MWI, one can refute MWI and insist on the collapse of the incoherent superposition to a pure state. The question is whether there could be an experiment to test these two interpretations.
 
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tom.stoer said:
And now we talk about an interpretation. Instead of interpreting the incoherent superposition as independent branches in MWI, one can refute MWI and insist on the collapse of the incoherent superposition to a pure state. The question is whether there could be an experiment to test these two interpretations.

And the answer to that question, which was the point of my very first post before getting side tracked by linguistic hair-splitting, is, again, "Yes, in principle". I linked to this overview which discusses empirical means of distinguishing between no-collapse and collapse quantum mechanics and cites some specific proposals and already performed preliminary experiments. It's not a settled issue by any means, but neither is it an "In principle impossible to settle" issue.
 
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LastOneStanding said:
By "Copenhagen interpretation", it's reasonable to assume the OP meant what nearly everyone mean by the term today.
I find it difficult to do that, because I think the "standard" version of the CI is pretty silly, and possibly also logically inconsistent.

LastOneStanding said:
Instead, we'll ask, "Can Many Worlds be empirically distinguished from other well-defined models of QM?" The answer to that is yes. MW is empirically distinguishable from (and has been experimentally preferred over some) variants of QM of involving wavefunction collapse. Whether it can be empirically distinguished from other non-collapse variants is not yet clear.
I would consider those "variants" different theories. I don't doubt that they, or at least some of them, are distinguishable from QM in principle, because whoever came up with these alternatives probably made sure that they would be.

LastOneStanding said:
Actually, you just described Many Worlds pretty well, so apparently you don't need empirical convincing of it. All Many Worlds quantum mechanics, at its most basic, consists of is the claim that wavefunctions don't collapse and so the universe's wavefunction stays in an overall superposition.
To me, this is just quantum mechanics...except maybe for the idea that there's a wavefunction of the universe. That should probably be considered an MWI idea. "Copenhagenish" interpretations don't say that it's fundamentally wrong to apply QM to large systems, but they put a lot of emphasis on the measurement, and this suggests that it may not make sense to include yourself in the wavefunction.

LastOneStanding said:
If you think this view is compatible with Copenhagen, then I'll reiterate that I think your use of the word is very non-standard.
You're probably right about that. This reminds me of this quote by Asher Peres:
There seems to be at least as many different Copenhagen interpretations as people who use that term, probably there are more. For example, in two classic articles on the foundations of quantum mechanics, Ballentine (1970) and Stapp (1972) give diametrically opposite definitions of “Copenhagen.”​
Source: http://arxiv.org/abs/quant-ph/9910078
 
  • #14
tom.stoer said:
I guess you will agree to the following remark: decoherence does not cause a collaps to one pure state but only an effective diagonalization of the reduced density matrix (which still dos not correspond to a pure state). So the generalized quantum state "dead and alive" decoheres to "either dead or alive". But for a single cat still both possibilities are contained in the reduced density matrix. So decoherence
a) does explain why we observe a classical state of the cat, but
b) it does not tell us which state (either "dead" or "alive") will be observed.
So - even taking decoherence into account - in some sense there is still a collapse of the density matrix "dead or alive" to one pure state, e.g. "dead".
Yes, I agree, there's still some sort of "collapse", but now we're talking about a kind of "collapse" that doesn't contradict the MWI.
 
  • #15
LastOneStanding said:
Wavefunction collapse is a component of the Copenhagen interpretation (at least, the modern take on it), and is the entire reason the latter has led to the so-called measurement problem. Since collapse is a one-way, non-unitary process, it leads to theoretically distinguishable predictions of collapse vs. no-collapse QM. I have never seen the Copenhagen interpretation not defined with, in part, wavefunction collapse so while you're perfectly entitled to your own private definition, I think it's a very non-standard one and certainly not what the OP had in mind with the question.

The term "wavefunction collapse" does not appear in books published before 1975, so people like Bohr, Feynman, Einstein had probably never heard of it. (I know many people use the term, but what it means to them in terms of observable phenomena I have no idea.)
 
  • #16
gadong said:
The term "wavefunction collapse" does not appear in books published before 1975, so people like Bohr, Feynman, Einstein had probably never heard of it. (I know many people use the term, but what it means to them in terms of observable phenomena I have no idea.)
I thought it was mentioned in von Neumann's book from 1932, which I haven't read myself. Maybe he called it something else. "Reduction of the state vector" is another term for it.
 
  • #17
LastOneStanding said:
If you mean we don't have the technology for such an experiment, then that's true. If you mean such an experiment is impossible in principle, that's not true. There may or may not be an experiment that will distinguish MWI from other no-collapse interpretations; however, there are theoretically measurable difference between MWI and collapse interpretations like Copenhagen. In particular, measurement is theoretically reversible in MWI while it is not in Copenhagen. Quantum decoherence makes it questionable whether such experiments will ever be possible in practice—but that is different from there being no such experiment, full stop. See here for a more detailed overview.

The way I think of it, Copenhagen is not so much a precise physical theory as it is a recipe for getting testable predictions out of quantum mechanics. Wave function collapse is really part of the recipe, and not part of the ontology. You can interpret as saying: After a measurement, you can act AS IF the wave function has collapsed to the eigenstate of the observable that was measured corresponding to the eigenvalue obtained. I don't think Copenhagen treats this collapse as a physical event.

You can certainly make a theory of wave function collapse so that it's interpreted as a literal event, but I don't think Copenhagen does that.

Actually, it seems to me that the intuitive idea of a wave function collapsing as a physical event has serious difficulties if you have more than one particle. With more than one particle, the wave function is a function on configuration space, rather than physical space, and so it's not possible in any straight-forward way to interpret "collapse" as some rapid or instantaneous change of a field.
 
  • #18
Fredrik said:
To me, this is just quantum mechanics...except maybe for the idea that there's a wavefunction of the universe. That should probably be considered an MWI idea. "Copenhagenish" interpretations don't say that it's fundamentally wrong to apply QM to large systems, but they put a lot of emphasis on the measurement, and this suggests that it may not make sense to include yourself in the wavefunction.

Well, insofar as a "Copenhagenish" interpretation suggests that, such an interpretation/variant/whatever you wish to call it is empirically distinguishable from MWI. Now we are getting extremely deep into Gedanken experiment territory as the technology required would be truly fantastic (and the experiments possibly unethical); however, in MWI, not only does it make perfect sense (and is required) to include the experimenter in the quantum state, sufficient control (i.e. the ability to isolate from the environment to such a degree that decoherence does not occur) of the combined experimenter+experiment system allows coherent superpositions. Whether it is because of objective collapse or because of whatever reason a "Copenhagenish" interpretation disallows it, macroscopic objects (including people) cannot, in principle, be in coherent superposition in some variants, and they can in MWI.

Perhaps it is possible to work out a less extreme experimental difference between MWI and your Copenhagenish interpretations, but the existence of one in principle is sufficient to answer the OP's question in the affirmative. In the meantime, I will amuse myself by imagining physicists being hurled at high velocity at a double slit in the hopes of observing an interference pattern:rofl:
 
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  • #19
gadong said:
The term "wavefunction collapse" does not appear in books published before 1975, so people like Bohr, Feynman, Einstein had probably never heard of it. (I know many people use the term, but what it means to them in terms of observable phenomena I have no idea.)

Von Neumann, in his treatment of quantum mechanics, describes two types of processes associated with a wave function: (1) Smooth evolution according to the Schrodinger equation, and (2) projection of the wave function onto an eigenstate following a measurement. This second type process is what people mean by "wave function collapse", I think, whether or not the term was used.
 
  • #20
stevendaryl said:
The way I think of it, Copenhagen is not so much a precise physical theory as it is a recipe for getting testable predictions out of quantum mechanics. Wave function collapse is really part of the recipe, and not part of the ontology. You can interpret as saying: After a measurement, you can act AS IF the wave function has collapsed to the eigenstate of the observable that was measured corresponding to the eigenvalue obtained. I don't think Copenhagen treats this collapse as a physical event.

That's a perfectly reasonable framework; however, it's getting rather close to bare instrumentalism. Instrumentalism, of course, is a reasonable position to take, but you're essentially removing yourself from the "interpretation game" when you take it. I think this is fine as a working theory, since it's entirely sufficient for anyone who just uses QM. However, it shouldn't be mistaken as a genuine interpretation of QM's formalism, nor should it be taken as eliminating the need for one—for, as we are now discussing, different wavefunction ontologies are, in principle, distinguishable and so the practical instrumentalist/agnostic position will (hopefully) not be tenable forever.

The point I'm making here is that we need to compare apples to apples. There are variants of quantum theory that arise from interpreting (and/or extending) the formalism of QM in different ways. MWI is one, Bohmian mechanics is another, as are various objective collapse models, and so on. Some of these are in principle testable, and it's important that that be understood. On the other hand, it doesn't make sense to compare MW with your Copenhagen/instrumentalism viewpoint, since all it is is the neutral position you adopt in the absence of sufficient evidence in favour of a particular QM interpretation. Which is fine, but it shouldn't stop us from working on devising experiments that will yield such evidence.

Of course, some people go a ways further than you do and adopt the position that "a recipe for getting testable predictions" is all QM is, that there is no independent wavefunction, no epistemic framework, nothing. That position—ontological instrumentalism, instead of just practical instrumentalism—is an interpretation of QM, insofar as it denies an independent existence to all the referents of QM's formalism. Whether such an interpretation is also experimentally testable, I'm less sure. Maybe evidence for objective wavefunction collapse would count as evidence against it. In any case, it doesn't sound like this is your position anyways so this is beside the point.
 
  • #21
LastOneStanding said:
That's a perfectly reasonable framework; however, it's getting rather close to bare instrumentalism. Instrumentalism, of course, is a reasonable position to take, but you're essentially removing yourself from the "interpretation game" when you take it.

I don't really think of Copenhagen as an interpretation. It's a way to go ahead and do physics without having to wait for a real interpretation to come along.
 
  • #22
stevendaryl said:
I don't really think of Copenhagen as an interpretation. It's a way to go ahead and do physics without having to wait for a real interpretation to come along.

Right, so, just to emphasize: what you're calling Copenhagen is known in philosophy of science as instrumentalism, and in the context of QM is generally called shut-up-and-calculate. I still don't agree at all that that is what is generally meant by the term Copenhagen, but as long as we both understand what's being referred to I'm not overly fussed by your preferred word. As I said, the important part is that people agree (whatever they choose to name the position of "not adopting a particular ontological interpretation and just using the formalism") there are such interpretations and they are, in principle, experimentally distinguishable.
 
  • #23
LastOneStanding said:
Well, insofar as a "Copenhagenish" interpretation suggests that, such an interpretation/variant/whatever you wish to call it is empirically distinguishable from MWI.
They may suggest that the wavefunction of the universe doesn't make sense, but they don't actually say it. I mean, they don't say that we're definitely going to get nonsense if we try to apply QM to the universe. The problem is just that these interpretations do not assign an interpretation to a wavefunction that includes yourself.

LastOneStanding said:
Whether it is because of objective collapse or because of whatever reason a "Copenhagenish" interpretation disallows it, macroscopic objects (including people) cannot, in principle, be in coherent superposition in some variants, and they can in MWI.
What I would consider "Copenhagenish" interpretations don't forbid macroscopic superpositions, but it's clear now that you include several things that I would consider alternative theories in that category.

LastOneStanding said:
In the meantime, I will amuse myself by imagining physicists being hurled at high velocity at a double slit in the hopes of observing an interference pattern:rofl:
It's been a while since I had that image in my head. :smile:
 
  • #24
After some posts on interpretations of interpretations I am asking again whether there are experiments which allows us to distinguish between "MWI with coherent superpositions" and "Neumann's state vector reduction", both formulated in terms of density matrices and taking decoherence into account.

@LastOneStanding: http://plato.stanford.edu/entries/qm-manyworlds/#5 seems to be interesting
 
  • #25
Are there more variants of the CI than there are versions of the MWI?
 
  • #26
Try to read:

Quantum Theory as a Universal Physical Theory
David Deutsch, 1985 section 8: A THOUGHT EXPERIMENT

It is a little odd, but you asked for even thought experiments, so... Here it is. I don't know how satisfied this will leave you, though.
 
  • #27
VforVendetta said:
Try to read:

Quantum Theory as a Universal Physical Theory
David Deutsch, 1985 section 8: A THOUGHT EXPERIMENT

It is a little odd, but you asked for even thought experiments, so... Here it is. I don't know how satisfied this will leave you, though.
This paper, VforVendetta: http://link.springer.com/article/10.1007/BF00670071 ?
 
  • #29
StevieTNZ said:
There were other stuff I could find, like...

http://arXiv.org/abs/0809.4422v1
http://arxiv.org/abs/0903.1564v2
http://arxiv.org/abs/1209.3445

I'd also reccomend reading:

Understanding Deutsch’s probability in a deterministic multiverse
H. Greaves (2004)

Worlds in the Everett interpretation
David Wallace
Studies in History and Philosophy of
Modern Physics 33 (2002) 637–661

Everett and structure
David Wallace
Studies in History and Philosophy of
Modern Physics 34 (2003) 87–105

Everettian rationality: defending Deutsch’s
approach to probability in the Everett
interpretation
David Wallace
Studies in History and Philosophy of
Modern Physics 34 (2003) 415–439

The Interpretation of Quantum Mechanics:
Many Worlds or Many Words?
Max Tegmark

Nine formulations of quantum mechanics
Daniel F. Styer, a) Miranda S. Balkin, Kathryn M. Becker, Matthew R. Burns,
Christopher E. Dudley, Scott T. Forth, Jeremy S. Gaumer, Mark A. Kramer,
David C. Oertel, Leonard H. Park, Marie T. Rinkoski, Clait T. Smith,
and Timothy D. Wotherspoon

Decoherence, the measurement problem, and interpretations of
quantum mechanics
Maximilian Schlosshauer
REVIEWS OF MODERN PHYSICS, VOLUME 76, OCTOBER 2004

Decoherence, einselection, and the quantum origins of the classical
Wojciech Hubert Zurek
REVIEWS OF MODERN PHYSICS, VOLUME 75, JULY 2003

If one day I have time, I'll try reading all of them as well... It is just that we need to have a job to put food in our tables, so there is not always time to put in the reading of almost 300 pages of very interesting physics...

This is what I could find that would be relevant enough in a first search.
 
  • #30
Thanks for the thorough list. When I return to study next year (I hope) I will have my university credentials to access some of the material you cite.
 
  • #31
Zmunkz said:
In principle... probably, yes. Every interpretation of a model has implications along with it, and it is just a matter of time before someone clever enough comes along and sees a way to measure the reality of one set of implications verse another.

That's not true.

Many interpretations have been deliberately cooked up so its impossible to tell the difference between it and the formalism.

In fact most (but not all) interpretations is simply an argument about the meaning of probability.
http://math.ucr.edu/home/baez/bayes.html

Thanks
Bill
 
  • #32
VantagePoint72 said:
Right, so, just to emphasize: what you're calling Copenhagen is known in philosophy of science as instrumentalism, and in the context of QM is generally called shut-up-and-calculate. .

Yes and no. It is part of a group of interpretations that has observations as its primitive (philosophers likely would call it instrumentalist - although I wouldn't because it goes well beyond instruments in actual experiments) that differ purely in how the interpret probability. I would classify all those in the shut-up and calculate group.

Thanks
Bill
 

What is the Copenhagen interpretation?

The Copenhagen interpretation is a popular interpretation of quantum mechanics proposed by Niels Bohr and Werner Heisenberg in the 1920s. It states that particles do not have definite properties until they are measured and that the act of measurement affects the outcome of the experiment. This interpretation also includes the idea of wave-particle duality, where particles can behave as both waves and particles.

What is the Many-Worlds interpretation?

The Many-Worlds interpretation, also known as the Everett interpretation, is a controversial interpretation of quantum mechanics proposed by Hugh Everett III in the 1950s. It suggests that every time a measurement is made, the universe splits into multiple parallel universes, each containing a different outcome of the experiment. This interpretation challenges the idea of wave-function collapse and suggests that all possible outcomes of an experiment exist simultaneously in different universes.

What is the difference between the Copenhagen and Many-Worlds interpretations?

The main difference between the Copenhagen and Many-Worlds interpretations is their explanation of the wave-function collapse. The Copenhagen interpretation states that the wave-function collapses upon measurement, while the Many-Worlds interpretation suggests that the wave-function never collapses and all possible outcomes exist in parallel universes. Additionally, the Copenhagen interpretation includes the role of the observer in determining the outcome of an experiment, while the Many-Worlds interpretation does not.

Which interpretation is more widely accepted among scientists?

The Copenhagen interpretation is more widely accepted among scientists as it is the traditional interpretation of quantum mechanics and is used in most textbooks and research papers. The Many-Worlds interpretation, on the other hand, is still a topic of debate and has not gained as much acceptance in the scientific community.

What are some criticisms of the Many-Worlds interpretation?

Some criticisms of the Many-Worlds interpretation include its lack of testability and falsifiability, as it suggests the existence of parallel universes that cannot be observed or proven. It also raises questions about the conservation of energy and the definition of "observers" in different universes. Additionally, some scientists argue that the Many-Worlds interpretation is unnecessarily complex and goes against Occam's razor, which states that the simplest explanation is usually the correct one.

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