Maui said:Matter looks solid under the classical mechanics treatment of human vision(as you say, you can see it - don't see how that's relevant, but whatever), but classical mechanics was never good enough. This argument has clearly evolved to an argument about personal tastes.
JK423 said:Have you ever observed a particle being in 2 places at once? The answer is 'no'. So, period. It's incorrect to use such phrases.
In the case that a particle would be in 2 places at once, we would scatter photons on the particle and we would see them being scattered, for example, both at places A and B. Which means that we would see flashes from two different points in space. That would be proof.Maui said:That depends on what you mean by "observed". We don't observe partciles but their effects after measurement. A particle interfereing with itself can be thought of as being in two places at once.
JK423 said:In the case that a particle would be in 2 places at once, we would scatter photons on the particle and we would see them being scattered, for example, both at places A and B. Which means that we would see flashes from two different points in space. That would be proof.
But, we don't observe such a thing. Everytime we make an observation, only one is the outcome and not many simultaneously.
And what do you mean with phrases like the one in bold? *can be thought of..* is just an interpretation of the formalism. We don't know anything more!
Dont forget that Bohmian mechanics have not been falsified, a deterministic theory which talks about particles always being in one place at a time! And agrees with experiment!
Not even Leggett's model can falsify Bohmian mechanics!
As a previous poster said, whch is true in my opinion, a good scientist must always assume as few things as possible, because only in this way there will be a new discovery!
And also, phrases like *being in two places at once* are mostly used to impress ourselves and others, non-physicists. However, the truth is more shameful: We don't actually know what's going on..
How would you argue that the (position) function [itex]x:\mathbb R\rightarrow\mathbb R^3[/itex] in the non-relativistic classical theory of a single particle with mass m doesn't describe what is actually happening to the particle? Perhaps you meant that you could argue that it's not an exact description of what's happening to any actual particle in the real world? You would be right of course, but that's not what I'm talking about. At the very least, this theory can be interpreted as an exact description of what's going on in a fictional universe. It's not obvious to me that QM can be interpreted that way.Maui said:Well, not liking what quantum mechanical expiments strongly suggest about what happens, certainly doesn't invalidate the straightfoward(imo) conclusions that flow from it. One could easily claim that classical mechanics is also not a true description of experiments at the macro scale.
I have spent a lot of time thinking about what definition of "theory" is the most appropriate for physics, and the definition I like the best is (loosely stated) "an assignment of a unique probability to each possible result of each member of some set of experiments". Given that definition, or any other definition that's even close to reasonable, it doesn't make sense to classify theories as "right" or "wrong". "Right" can only mean "exactly right", and none of our theories are. (The only possible exception is QM). If we choose to label them "right" or "wrong", they'd all be in the "wrong" category. The only kind of (good vs. bad) classification of theories that makes sense to me is to say that a theory is as good as its predictions. The more accurate the predictions are, the better the theory.Maui said:Edit: I now remember reading a post of yours where you said something to the effect that all our models are likely wrong. That sheds some light on why you seem to react the way you do to the interpretational side of quantum experiments.
Fredrik said:Another reason not to think of QM as a "description of what actually happens" is the discussion in this thread. Consider the wavefunction [itex]\psi[/itex] that satisfies [itex]\psi(\vec x)=N\exp(-a\vec x^2)[/itex] for all x. If someone insists that a wavefunction is telling us what's "actually happening", then I would interpret that statement as saying that this wavefunction represents a particle that's "actually" spread out all over space, with "most of it" near 0. But there doesn't seem to be any valid arguments against the possibility that every particle has a position (represented by just a triple of real numbers), no matter what its wavefunction is.
I'm not saying that I think particles have positions. My point is just that since there seems to be nothing in QM that rules it out, it's very hard to argue that a particle's wavefunction is telling us what's "actually happening" to the particle. I don't think QM + the experiments that check the accuracy of its predictions give us enough information to say that we know what's "really happening" between state preparation and measurement.
In my opinion, no. Decoherence theory explains why it's hard to prepare superpositions, why a superposition can't be the result of a measurement, etc., but it doesn't give us any insights into what a particle with wavefunction ψ is "really doing".JK423 said:But.. If we accept that nature is probabilistic and we include decoherence in all this, then are we able to say that QM describes *what actually happens*?
Ok, imagine that QM was not probabilistic and that decoherence theory could predict exactly in which state the pure state vector will collapse. Then, according to what you say, you would still think that QM is not a description of "what really happens" since the probabilities isn't your issue.Fredrik said:In my opinion, no. Decoherence theory explains why it's hard to prepare superpositions, why a superposition can't be the result of a measurement, etc., but it doesn't give us any insights into what a particle with wavefunction ψ is "really doing".
Fredrik said:Another reason not to think of QM as a "description of what actually happens" is the discussion in this thread.
If QM was not probabilistic, then it wouldn't be QM, so I don't really understand the question.JK423 said:Ok, imagine that QM was not probabilistic and that decoherence theory could predict exactly in which state the pure state vector will collapse. Then, according to what you say, you would still think that QM is not a description of "what really happens" since the probabilities isn't your issue.
Or is it?
It can be a complete description of what actually happens. But in the posts I linked to above, I argued that a) this seems to lead to many worlds, and b) there's room for additional assumptions on top, like the assumption that every particle has a position. (This means that we can at least say that the fantastic agreement between theory and experiment doesn't prove that QM describes reality in the sense you're suggesting).JK423 said:If we don't consider the probabilistic side of QM, then the wavefunction seems to be a complete description of 'what actually happens'. There are just no particles! There are only wavefunctions.. Why we see particles? We dont... It's just that the wavefunction is localized in space, and QM predicts the wavefunction to be localized in occassions like measurements. So, everything is predicted by QM. How this is not a complete description of "what actually happens"?
It's not just the fact that non-trivial probabilities are involved even when the states are pure. Classical mechanics can also be interpreted as a probabilistic theory, but the theory first produces something that can clearly be thought of as an approximate description of what actually happens, and then we can use that description to assign a probability of either 0 or 1 to each possible result. QM on the other hand skips over the first step (the description of what actually happens) and goes straight for the probability assignment.JK423 said:It's just the probabilities that makes it difficult to accept QM as a complete theory..
You can argue for this if you define "description" in a way that makes the claim trivially true. But this would make the word useless, so it would be better to just stop using it altogether.BruceW said:QM is the best description of what actually happens.
Sorry about that. I heard the email notifications while I was typing my previous two posts in this thread, but I assumed that they were notifications of PMs, not notifications that my inbox was full, so I figured I could just look at them after I was done here. I have deleted a few messages now.Fyzix said:Fredrik, I wrote a long response to your PM, but your inbox was too full to be able to send it to you.
I don't think I want to get into a discussion about my thoughts on how QM can be interpreted as describing many worlds. It would take more time than I have right now. Also, I'm not sure why my previous attempts to explain the "splits" in this MWI to you didn't help, so I don't know what I should be saying differently. It's possible that I will have a better way of explaining these things once I've thought them through in more detail, but I'm giving this a low priority right now.Fyzix said:So how is it different from the other MWI's?
In the case of Schroedingers Cat, how does your "splitting" differ from the splitt/decoheret branching of Wallace/Deutsch?
Bohm says that particles have positions. I find it hard to accept that, and that any solution of the Schrödinger equation can describe a particle. They seem mutually exclusive to me. So if Bohmian mechanics describes reality (something I don't really believe but also haven't ruled out), I would say that QM doesn't.Fyzix said:Also you can still insist that QM is a description of reality without invoking collapse.
Gerard t Hooft has shown this with his models, other people have made models, deBroglie Bohm etc. etc.
Fredrik said:You can argue for this if you define "description" in a way that makes the claim trivially true. But this would make the word useless, so it would be better to just stop using it altogether.
It describes what is observed by measurement - that is, the phenomena or appearances. Just like relativity. However, "superposition" isn't a measurable but as Fredrik indicated, it's part of the math of the theory that is used to make predictions about what can be observed.BruceW said:The reason QM is a description of what actually happens is because it is backed up by experiment. How else could you define "description"? [..]
BruceW said:So we can only say that what actually happens is what we actually measure in experiments?
And that theory should never be considered to represent what actually happens?
If that's what you were saying, then I guess I agree. Experimental results will always be true, but theories come and go.
Edit: Not trying to hate on theory itself. Even the theories that have been proven wrong (i.e. classical mechanics) are still useful in a certain limit.
I wouldn't define it. See post #40.BruceW said:The reason QM is a description of what actually happens is because it is backed up by experiment. How else could you define "description"?
Those two are certainly the only candidates for "best theory". I'm inclined to say that QM is the better one, but I remain unconvinced that it makes sense to say that it describes something. (OK, I think it might make sense to say that it describes a physical system that includes many worlds, but I don't think it makes sense to say that it describes a single universe, not even a fictional one).BruceW said:The reason I said 'best description' is because the theory is very general, and can be used in many different situations. I suppose General relativity would also be a candidate for the honour of 'best description'.
Would you elaborate a bit more? Seems to be promising quantum ontology...?wawenspop said:something called a particle 'existing' outside space-time (IMO an algorithmic entity) and it simply pops in and out of our reality by giving values through its wave function boundaries when asked by an observing photon or particle (actually the wave function's of those)
CyberShot said:Don't you think this should be the goal of physics, and not just meta-physics/philosophy? Physics should be about deducing the rulebook of the Universe. Why should we leave out thoughts about "what's physical and what's real?" How else are we supposed to "figure out the mind of God?"...
xts said:Would you elaborate a bit more? Seems to be promising quantum ontology...?