Measurements problem - QED

In summary, the measurement problem in quantum physics is a set of open interpretational and philosophical questions regarding the relation between micro- ("quantum") and macro ("classical") levels of physical theories. It has been a topic of fascination and excitement for many students of quantum mechanics and has led to proposed experimental tests by physicists like Tony Leggett. While some may view it as purely philosophical, it also has potential implications for areas such as quantum cosmology. The problem can be summarized by questions such as whether physical observables have values when not measured, and how measurement affects them. There is ongoing debate and discussion on this topic within the scientific community.
  • #36
reilly said:
Could someone explain to me why Schrodinger's Cat has anything to do with QM?

My people usually add in such cases: le zaazel!

Yes. The Quantum Physics must be naturally connected with the Classical Physics.

Regards, Dany.
 
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  • #37
tommyburgey said:
What is the measurement problem and why is it such a problem?

Now let me go two steps further. The isolated measurement or the collection of the measurements is only the data base. What we intend to do with it? How we define what the knowledge and the process of the acquisition of knowledge is? How the evolution of the knowledge is described?

You should not misinterpret me. I have no background in philosophy and it is last thing that I have in my mind. All that interested me is how the collection of facts may be organized using the suitable mathematical languages. I suggest reading more about the process of the acquisition of knowledge in E.P.Wigner “The problem of Measurement” (AJP, 31, 6 (1963), W&Z, p.324).

Here I would like to say more about the evolution of the knowledge. Indeed we do not know the laws of it yet. But we must use it at least intuitively similarly as we use equations of motion. For this reason I insist to use history of physics and was so rude in my post # 16. If “all conceptual problems of QM are already solved a long time ago”, we understand everything today. It is obviously wrong statement. Therefore some inaccuracies were made in the past. They should be identified and corrected. This is the only way to progress I know. And even after the more adequate theory is formulated, it is clear that something will remain wrong, the additional measurements will be required and further adjustment will be made.

I have year long history of discussions with Reilly here in PF. I was so glad to read his post that even suggested adding:” Could someone explain to me why Schrodinger's Cat has anything to do with QM, le zaazel!?”
Perhaps it is wishful thinking, but Reilly did not reject my statements. I will explain to you what do they mean:

1)the def of the objective reality: entire rejection of M. Born statistical interpretation of QM;

2)the statement that the third Newton law governs the measurement procedure: entire rejection of J. von Neumann theory of measurements, namely, the state of the system under test and the measurement apparatus is not described by the direct product of the individual states;

3)the statement that the physical theory must explain the collapse: entire rejection it’s treatment as a postulate (it was pointed out by J. von Neumann that it can’t be treated as a postulate, but later “philosophers” did).

4)“Could someone explain to me why Schrödinger’s Cat has anything to do with QM?”: entire reformulation (generalization) of all of the Classical Physics (Newtonian mechanics, Maxwell ED and Einstein gravitation) according to W.R. Hamilton and E. Schrödinger conjecture.

I have no doubt that this should be done and will be done. Now you understand what is said: "If you want to strike fear into the eyes a physicist; mention the measurement problem".

Regards, Dany.
 
  • #38
What about decoherance? I would think that practical experiments in maintaining entanglement in anticipation of developing quantum computing technology would begin to give them a handle on the problem of "when the wavefunction collapses".

—John
 
  • #39
JDługosz said:
What about decoherance? I would think that practical experiments in maintaining entanglement in anticipation of developing quantum computing technology would begin to give them a handle on the problem of "when the wavefunction collapses".

—John

I believe that the correct answer to the problem "when collapse occurs" is that it doesn't occur in Copenhagenian sense at some instant, but instead decoherence makes it appear as if the collapse had occured. If this is what you meant, then I agree.

But if somebody attempts to explain that there is no problems with collapse, it is still appropriate to ask the "when" question. It at least directs the conversation a little bit.

Still, the decoherence does not solve all collapse problems. Eventually the experimenter gets some measurement results, so some kind of real collapse must occur somewhere somehow in the experiment.
 
  • #41
jostpuur said:
if you don't know what the quantum mechanical measurement is, you can pretend that you don't have any problems with it, and nothing will force you to admit that you have no idea what it is.

Equally well, you can pretend that you have problems with it, and nothing will force you to admit that you have no idea what it is.

jostpuur said:
I believe that the correct answer to the problem "when collapse occurs" is that it doesn't occur in Copenhagenian sense at some instant, but instead decoherence makes it appear as if the collapse had occured. If this is what you meant, then I agree.

Pity. The dispersion in/of time is the same property of the quantum world as the dispersion in/of space. If you accept the HUP and the special relativity you should understand that your question and the question where the electron is located in the hydrogen ground state is the same question. The measurements allow to “see” that properties of the QM systems. The collapse have nothing to do with it, the collapse is the property of the measurement equipment. You ask the wrong question. Mathematically, all you need to know are the properties of 2X2 or 4X4 matrices.

I don’t think that the problems are with the physics or with the math. There is some deep psychological trouble with QM in spite that our brain provides the every day practical example how it works. Consider for example what the referred by genneth (http://arxiv.org/abs/quant-ph/0205039, p.49) writer quoted without ref.:

“Look at classical physics, how nice it is: We can measure a particle’s position and momentum with as much accuracy as we would like. How limiting quantum theory is instead. We are stuck with

Delta(x)*Delta(p) >=h/2

And there is nothing we can do about it. The task of physics is to sober up to this state of affairs and make best of it.”

In QM delta(x)*delta (p) may have any real value from h/2 to infinity, but in classical physics delta(x)*delta (p) = 0 only. It is enough to participate intelligently at the first year of math at base school to know that 2>1, not necessary to attend meetings on the foundations of physics and to quote Winston Churchill.

Regards, Dany.
 
  • #42
My preferred position is to view time as on an equal footing with any other observable, i.e. there's clock time, but no absolute time. In classical mechanics this is hardly a problem, see de Donder-Weyl mechanics or what Rovelli calls relativistic mechanics. Essentially, instead of calculating the correlation between "dependent" variables and the "independent" one called time, we just calculate correlations between observables. In quantum, we've actually still not got a problem, as far as we can derive a propagator, which basically gives the correlation between observing one event and another. We can actually come up with quantum models which lack a time variable. However, the situation with multiple events is more complicated. Hartle has his generalised, history-based quantum mechanics (see http://arxiv.org/abs/gr-qc/0602013), and Rovelli (and his bunch) proposes instead that event ordering is emergent from the dynamics (see http://arxiv.org/abs/gr-qc/0610140). I personally find the latter to be easier to understand, and better physically motivated.

However, all of this should be counterbalanced by the fact that we've never come across an experiment in quantum mechanics which violates our theory. Whenever we've properly taken into account the equipment we're measuring with, and the precise set up, we can always calculate the relevant probabilities. This is why experimentalists never worry about the measurement problem: they just do it! Theoretically, we'd (or some) like to have a physical theory which doesn't force the introduction of the details of measuring equipment -- which is why volumes have been written on this subject.
 
  • #43
genneth said:
I personally find the latter to be easier to understand, and better physically motivated.

I personally find all four papers referred by you have nothing to do with physics. There are no refs on A.Einstein, E. Schrödinger, W. Heisenberg, P.A.M.Dirac, E.P.Wigner and C.N.Yang. It is not possible to formulate the physical theory of measurements without well defined notion of the objective reality and I don’t know how it may be done without language of the theory of the continuous groups.

You try to switch the discussion to the nature of time in QM and problems of QG. PF rules suggest not repeating the same statements under different names in the different sessions. The questions related to time in QM are discussed in “nature of time” session. I consider any attempt to formulate the adequate theory of QG before relativistic QM hopeless. If you are interesting, my POV is presented in “How to explain the benefits of string theory to my grandmother...” session.

Regards, Dany.
 
  • #44
genneth said:
... see de Donder-Weyl mechanics ...

Anonym said:
I personally find all four papers referred by you have nothing to do with physics. It is not possible to formulate the physical theory of measurements without well defined notion of the objective reality ...

Perhaps some will be interested in my results
http://xxx.lanl.gov/abs/hep-th/0407228
http://xxx.lanl.gov/abs/hep-th/0512186
http://xxx.lanl.gov/abs/hep-th/0601027
showing that quantization based on de Donder-Weyl mechanics automatically determines what objective reality is: the Bohmian reality.
 
  • #45
I hate to interrupt (but I will) this festivities. Please use, as far as you can, peer-reviewed citations. Unless this is a speech, conference proceedings, or lecture notes of prominent physicists, we much prefer published work rather than ArXiv uploads. If they have been published, please give a full reference alongside the ArXiv links. If they have not been published, why not?

Zz.
 
  • #46
ZapperZ: an exceedingly good idea, I usually mean to, though sometime forget to check, esp. if I consider the authors to be good authorities.

EPR in relational interpretation: http://www.arxiv.org/abs/quant-ph/0604064 in Found.Phys. 37 (2007) 427-445

Dany: That paper cites some of authors in your list.
 
  • #47
ZapperZ said:
I hate to interrupt (but I will) this festivities. Please use, as far as you can, peer-reviewed citations. Unless this is a speech, conference proceedings, or lecture notes of prominent physicists, we much prefer published work rather than ArXiv uploads. If they have been published, please give a full reference alongside the ArXiv links. If they have not been published, why not?
The journal references are also written down on these links, as can be easily seen. I think it is more practical to give the arXiv links because it makes easier to download that papers by those who are interested. It is actually a common practice in high-energy physics community, and I do not see why other physicists should not adopt this beautiful practice. Anyway, if you still think that I should write the journal references in the posts themselves, I can do that as well.
 
  • #48
Demystifier said:
The journal references are also written down on these links, as can be easily seen. I think it is more practical to give the arXiv links because it makes easier to download that papers by those who are interested. It is actually a common practice in high-energy physics community, and I do not see why other physicists should not adopt this beautiful practice. Anyway, if you still think that I should write the journal references in the posts themselves, I can do that as well.
Yes, otherwise, the forum will be restricted only to those few people who have access to the journal references (maybe this is what ZapperZ wishes?).
 
  • #49
Demystifier said:
The journal references are also written down on these links, as can be easily seen. I think it is more practical to give the arXiv links because it makes easier to download that papers by those who are interested. It is actually a common practice in high-energy physics community, and I do not see why other physicists should not adopt this beautiful practice. Anyway, if you still think that I should write the journal references in the posts themselves, I can do that as well.

That is why I requested that the actual reference to the published work be cited along side the Arxiv link. And yes, I'm aware that HEP community often cites ArXiv papers (since I'm surrounded by high energy physicists at work). While we allow some of that in the particle physics and BTSM forum, we would like to try to use published work in the remaining physics sub-forums.

lightarrow said:
Yes, otherwise, the forum will be restricted only to those few people who have access to the journal references (maybe this is what ZapperZ wishes?).

I'm not even going to dignify that with a response.

Zz.
 
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  • #50
maybe vacuum energy causes the interferance pattern! (i'm excited)

someone tell me if I'm a genius
 
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  • #51
ZapperZ said:
That is why I requested that the actual reference to the published work be cited along side the Arxiv link. And yes, I'm aware that HEP community often cites ArXiv papers (since I'm surrounded by high energy physicists at work). While we allow some of that in the particle physics and BTSM forum, we would like to try to use published work in the remaining physics sub-forums.
OK, I will try to obey this rule in the future.
 

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