kashiark said:an atom goes through a particular nuclear reaction and emits a left-handed and right-handed particle. after the particles have traveled to opposite sides of the universe, if you measure the handedness of one you instantly know the other's which is information moving faster than the speed of light. what was the answer to this paradox?
That's one way of looking at it.DrChinese said:They thought that QM could not be a complete theory because it led to "spooky" predictions. However, modern tests show that these spooky things happen.
There's no paradox because as far as anybody knows there's no information moving faster than the speed of light.kashiark said:an atom goes through a particular nuclear reaction and emits a left-handed and right-handed particle. after the particles have traveled to opposite sides of the universe, if you measure the handedness of one you instantly know the other's which is information moving faster than the speed of light. what was the answer to this paradox?
ThomasT said:EPR's conclusion was that the quantum theory was an incomplete theory of physical reality -- and, depending on what one takes 'physical reality' to mean, then it either is or isn't. ...
ThomasT said:But quantum theory includes everything that's known wrt the physical reality revealed to our senses via the instrumental data. So, wrt that physical reality it's a complete theory. It accurately predicts statistical probabilities and correlations without a complete accounting of the underlying dynamics.
If you mean that 'instantaneous-action-at-a-distance' and/or ftl propagations have been experimentally demonstrated, then I disagree.
There's no paradox because as far as anybody knows there's no information moving faster than the speed of light.
Ilja said:But here there is no such ad hoc explanation - no realistic explanation is possible in principle.
Dmitry67 said:No single-history realistic explanation is possible,
Dmitry67 said:It is newbies question so its is not the place for MWI vs CI.
I just wanted to say that based on the recent polls, MWI is now #1 - the mainstream interpretation, or at least it is as popular as CI,
alxm said:I suspect the real #1 'interpretation' is the one I adhere to: the "Who the heck needs a damn interpretation?" interpretation.
Many physicists have subscribed to the null interpretation of quantum mechanics summarized by the sentence "Shut up and calculate!". While it is sometimes attributed to Paul Dirac[17] or Richard Feynman, it is in fact due to David Mermin.
jms5631 said:Hey Dmitry, I wonder which polls you are referring to, and what demographics of the physics community they represent, because MWI is surely not the most accepted interpretation in the enitre working physicist community. I'm aware of a single poll from a specific sampling of theorists that gives this result and several others that give opposite results, with MWI placing second and even last. I'm just say the MWI adherants should guard against being overzealous.
"Many worlds"-like interpretations are now considered fairly mainstream within the quantum physics community. For example, a poll of 72 leading physicists conducted by the American researcher David Raub in 1995 and published in the French periodical Sciences et Avenir in January 1998 recorded that nearly 60% thought many worlds interpretation was "true". Max Tegmark also reports the result of a poll taken at a 1997 quantum mechanics workshop.[36] According to Tegmark, "The many worlds interpretation (MWI) scored second, comfortably ahead of the consistent histories and Bohm interpretations."
Dmitry67 said:You need to sacrifice something: determinism, realism, causality, single history. If you can sacrifice single history then you can use MWI - it is realistic and deterministic, and only sacrifice is a single history.
Is there a theorem that proves this statement? I don't think so because there is a counterexample to this (Bohm).Dmitry67 said:No single-history realistic explanation is possible,
Ilja said:You don't need to sacrifice anything from your list: The pilot wave interpretation is deterministic, realistic, causal, and has a single history.
An important prediction of the Bohm theory, made in Bohm's original 1952 paper, is that the electron in the ground state of a hydrogen atom is in rest (cf. equation (3) above - s states have spherical symmetry and thus have constant phase), as the quantum force introduced by Bohm balances the classical electromagnetic potential.
Any measurement of the momentum of a ground state electron will give a non-zero result as predicted by quantum mechanics, but Bohm's theory argues that the act of measuring the momentum disturbs the electron at rest, resulting in a non-zero expection value. [3]
Experimental observation of the decay rates of muons bound in exotic atoms has shown, however, that ground state electrons are in fact in motion. Because of their mass, muons captured in higher states rapidly cascade to the ground state, and about 99 percent of the bound muons decay from the 1S state. If the atomic number of the hydrogen-like atom is high enough, the muon motion will be relativistic, and subject to time dilation. The data show that for moderate Z atoms, the observed lengthening of the muon decay time can be attributed to the relativistic time dilation.[4]
Since the motion of the muon has been demonstrated without any disturbance of the atom, it cannot be explained by disturbances related to the measurement process as with conventional measurements of the momentum of ground state electrons. An important conceptual prediction of the Bohm model, namely that ground state electrons are at rest, would seem to be contradicted by experimental evidence.
Demystifier said:Is there a theorem that proves this statement? I don't think so because there is a counterexample to this (Bohm).
This is nonsense. The measurement of motion of the muon disturbs the MUON, so the Bohm model predicts that the muon moves when its motion is measured, in agreement with experiments.Dmitry67 said:Since the motion of the muon has been demonstrated without any disturbance of the atom, it cannot be explained by disturbances related to the measurement process as with conventional measurements of the momentum of ground state electrons. An important conceptual prediction of the Bohm model, namely that ground state electrons are at rest, would seem to be contradicted by experimental evidence.
First, as I repeated many times, it can be made relativistic. Second, I don't know what do you mean by "handwaving", but all new features of Bohmian mechanics are strictly DERIVED from postulating one additional EQUATION. If you call it "handwaving", then all the best theories in physics are "handwaving" too.Dmitry67 said:Ooops, I forgot about it - for me this is worst interpretation: pure handwaving, plus even not relativistic.
Demystifier said:This is nonsense. The measurement of motion of the muon disturbs the MUON, so the Bohm model predicts that the muon moves when its motion is measured, in agreement with experiments.
Dmitry67 said:Ooops, I forgot about it - for me this is worst interpretation: pure handwaving, plus even not relativistic. I was thinking it had been proven to be false a long tie ago:
http://en.wikipedia.org/wiki/Bohm_interpretation#Comparison_with_experimental_data
Physical reality also refers to our objective records. For those who think of QM as being only about the objective records, then it's a complete theory. For those who think of QM as being about an underlying reality, then it's an incomplete theory.Ilja said:Physical reality is what exists independent of our possibility to observe it. QM does not even make claims what is this reality. Is the wave function real or not? What else, if anything, is real too? These questions are simply not answered.
Thus, it does not make sense to claim that QM is in some sense a complete description of reality
Ilja said:Fact is, there are simple realistic explanations of the violations of Bell's inequality in terms of realistic hidden variables and hidden FTL information transfer. But there is no realistic explanation of the violations of Bell's inequality without FTL. Moreover, we have a theorem, that there cannot be such explanations without FTL.
This is the ideal situation of falsification of a theory. No theory can be falsified in a more rigorous way. Instaed, usually almost every theory can be saved, given some falsification, by some (at least formally realistic) ad hoc explanation. But here there is no such ad hoc explanation - no realistic explanation is possible in principle.
But in your previous post you said that "motion of the muon has been demonstrated". How measuring the lifetime of the muonium demonstrates the motion of the muon?Dmitry67 said:No, you just measure the lifetime of muonium, you don't measure the muon itself.
Demystifier said:But in your previous post you said that "motion of the muon has been demonstrated". How measuring the lifetime of the muonium demonstrates the motion of the muon?
I see. But it looks as a classical explanation. On the other hand, lifetimes should be calculable from standard quantum mechanics, irrespective of the interpretation. In other words, this difference of the lifetimes should be encoded in properties of the wave function, which by itself says nothing about particle motions. Therefore, since the Bohmian interpretation uses the same wave functions as standard quantum theory, and since there is a GENERAL THEOREM stating that all measurable predictions are the same, the Bohmian interpretation also must explain this effect. To see in detail how exactly this happens in the Bohmian interpretation, I would need first to see an explanation with standard QM. If standard QM could not explain it (which I am convinced that it can), then yes, it would be a failure of the Bohmian interpretation, but moreover, it would be a failure of standard QM as well.Dmitry67 said:If the lifetime of muonium is longer then the lifetime of muon itself then it can be explained by the time dilation of the muon
