This doesn't really solve the problem that some people see with this scenario; it just states the problem. Yes, if you prepare two particles in an entangled state, then make spacelike separated measurements on them, you can get correlations that violate the Bell inequalities. That's the experimental fact. But not everyone is satisfied with that bare statement as an explanation of why this can happen.vanhees71 said:
Perhaps the notion of causality needs to be extended. That would be interesting to see. I still think that even then one should not say that the measurement of A causes the result of B. Whatever terminology is chosen it should be clear that the causality of A and B is different than what the usual and more restrictive meaning implies.PeterDonis said:
How can two events be causally connected, if the time order of these events are frame dependent?PeterDonis said:
That's precisely what I don't understand. What is problematic in this interpretation of the meaning of the quantum state, the socalled minimal statistical interpretation? For me the quantum state simply describes the probabilistic properties of a system, given a preparation procedure. In this case the preparation procedure provides two entangled photons, described (with sufficient precision) by a Bell state. This implies that the single-particle properties are maximally indetermined but being also, for each possible coincidence measurement of these properties, in a clearly specified sense strongly correlated. The cause of the correlations is simply the preparation in this state. In addition, within a microcausal QFT for sure it cannot be a causal influence between two space-like separated events. This explains all observed facts. So what is problematic?PeterDonis said:
They can if causal connection does not require that the events have an invariant time order. See post #140.vanhees71 said:
The fact that it doesn't give any account of why a particular result happens in a particular run of an experiment. It only gives probabilities.vanhees71 said:
Not when it comes to disrupting quantum theory!vanhees71 said:
The minimal statistical interpretation is just fine, what is problematic is how to apply it properly to those types of experiment. You want to "stop directly after" the measurements, but that is "too early". If the evaluation of the experiments includes grouping of measurement outcomes by a sort of post-selection, then the communication required for that post-selection must also be included in the description of the experiment.vanhees71 said:
If the two measurements commute, the relationship between them is symmetric, but as has already been pointed out, a one-way causal connection is not symmetric (that's what "one-way" means).Grinkle said:
A causal connection in which one event is the "cause" and the other is the "effect". That's a one-way relation.vanhees71 said:
vanhees71 said:
vanhees71 said:
Of course if you define "causal" to mean a one-way relation, then no relation between spacelike separated measurements can be "causal". But that's due to the definition you picked.vanhees71 said:
I would also add Duncan's "The Conceptual Framework of Quantum Field Theory" to this list.vanhees71 said:
It's possible because nature does it. Non-locality, in that sense, is part of nature. This is what QM tells us.agnick5 said:
It sounds harsher than I intended, but I wanted to get @agnick5 to really question why this is a problem. Dissatisfaction with QM is not totally unjustified, but that itself can't just be thrown into the ring like human dissatisfaction is some unimpeachable judgement on QM.Grinkle said:
There is no "unmeasured" particle. An entangled two particle state was prepared. Not two independent particles. That two-particle system was measured. @Vanadium 50 put in well in a previous post:Grinkle said:
That's exactly what you are doing here.Vanadium 50 said:
Agreed, thanks for pointing that out and highlighting Vanadium 50's snip.PeroK said:
People do say I'm snippy, that's for sure.Grinkle said:
I'm sorry if my previous response sounded harsh. But, why is something wrong? It may be counterintuitive, but try to fully justify why it's downright wrong! Wrong is in itself a harsh judgement (on QM)!agnick5 said:
It's not the definition I picked but the definition picked for centuries.PeterDonis said:
I agree.PeroK said:
Almost everybody believes thatPeroK said:
Of course there are lots of experiments that are taken to be evidence for the existence of electrons and photons. But it is misleading to think of them as "objects", in my opinion it is more natural to view them as special patterns of events in space-time.PeroK said:
Of course, any quantum description is about some well-defined measurement. For von Neumann projective measurements that's equivalent to a choice of a basis of eigenvectors of the self-adjoint operators representing the measured observables.DrChinese said:
There is no medium. The correlations are due to the preparation of the photon pair in an entangled state.DrChinese said:
I don't know, what you mean by "quantum equilibrium". The entangled two-photon state is not an equilibrium state.DrChinese said:
Within microcausal relativistic QFT there is no other logical interpretation than the conclusion that space-like separated events cannot be causally connected. I'm not aware of any realization of relativistic QT that's not a microcausal QFT. So I can't speculate whether there are consistent realizations where there are causal influcences between space-like separted events. It would need a completely new definition of spacetime structures and the very fundamental notion of causality. I don't see any necessity for introducing such problems given the contemporary state of observations.DrChinese said:
You are the one repeatedly claiming a causal connection between spacelike separated events, not I. I try to explain, why within the standard microcausal relativistic QFTs this cannot be right.DrChinese said:
Exactly, and that's why there cannot be a causal connection between the measurement choices nor between the detection events in the measurement if these are spacelike separted.DrChinese said:
Exactly, but @RUTA claimed otherwise, and that's why I argued against this claim.DrChinese said:
If A and B coexist with the entanglement source in one frame they coexist with it in any frame. The physics doesn't change under Poincare transformations, because microcausal QFT is Poincare-covariant and physical observables are Poincare invariant.DrChinese said:
It was not me, who introduced such claims. To the contrary I argued always against them!DrChinese said:
Have a nice weekend too :-).DrChinese said:Cheers and happy Friday!
I don't know what you mean by "standardized statistical outcomes". The statistics is correctly described by the probabilities as predicted from microcausal relativistic QFT. These are incompatible with the probabilities predicted by a class of theories which Bell called "realistic local hidden-variable theories". Note that Bell uses another meaning of the word "local" than what's used in the QFT community.agnick5 said:
There is no contradiction in this.agnick5 said:
Nothing happens to the other particle, at least not instantaneously. Within microcausal relativistic QFT a local measurement at A can have a causal influence at B only if these events are time-like or light-like separated. That's the whole point of the discussion.agnick5 said:
The single-particle states are maximally indetermined, i.e., they are described by maximum-entropy statistical operators. The two-particle state is maximally determined, i.e., it's a pure state. This implies the strong correlations between the single-particle measurements, i.e., entanglement. The correlations are already there due to the preparation of the two-particle system in the entangled state although the single-particle properties are maximally uncertain. There's no need for any FTL signalling, because the correlation is not caused by space-like separated measurements but by the preparation of the two particles in an entangled state.agnick5 said:
That's indeed what we discuss all the time in this thread :-).agnick5 said:
agnick5 said:
I took it to mean using classical probabilities relating to hidden variables; as opposed to using complex probability amplitudes as in QM.vanhees71 said:
Yes, this is generally correct.agnick5 said:
The word "exactly" is unfortunate, but there was a sort of explanation in a related thread which caused the discussion about words in this thread. In special relativity, different groupings of events into being simultaneous can explain how time dilation and length contraction can be consistent. The analog for quantum mechanics is to group different measurement outcomes based on the combined measurement settings, in a process called post-selection.agnick5 said:
You seem to have many different detailed questions. Let me suggest to ask them in a separate thread.agnick5 said:
The problem with "plain English" is that you cannot really communicate about these "quantum properties". The only precise way is to use mathematics. Nevertheless, one can of course always try to explain these things in a way that's understandable without this math, but the danger is huge to get it somehow inaccurate or even wrong.agnick5 said:
That's a very good description. I'd not say the particles are separated at all when they are prepared in such an entangled state. One should also be aware that even a single photon has no well-defined position in the sense of a point particle to begin with. It's impossible to localize a photon as you can localize a massive particle. That's another specialty of massless relativistic particles which can only be described by relativistic quantum-field theory. All we can know about them, given the quantum state they are prepared in, are the probabilities to detect a photon at a given place and time. The two photons in an entangled state have no individuality and they are thus not separated in any sense. All you can calculate is the probability to find two photons at given times and positions of the detector and their polarization (using also some polarization measurement device like a polarization filter or a polarizing beam splitter). So even the separation into two individual photons is only manifest after registration of these photons (with their polarization state when measured) by the corresponding detectors.agnick5 said:
I hope, I've made this clear above.agnick5 said:
I don't know, what you expect as "explanation". Physics doesn't explain why we observe phenomena as we do but describes these observations and provides theories to predict what we'll observe given some situation, and that's very well achieved concerning the correlations, which cannot be explained by any "local realistic hidden-variable theory", and that's the math describing quantum states in general, including these special "far-from-classical kind" called "entangled states".agnick5 said:
The most surprising result of the entire quantum business for me indeed is that this is not a contradiction, if you accept the result that nature is indeterministic. You can prepare a particle or photon in a state, where a given observable takes a precisely defined (determined) value. Then any measurement of this observable will give with 100% probability this determined value. However, for some observables you cannot prepare the particle in a state, where all of them take determined values at once. That's the content of the famous Heisenberg uncertainty relations. E.g., if you localize a particle very precisely, i.e., you determine its position very precisely, then necessarily its momentum is very imprecisely determined, i.e., when measuring the position of a such prepared particle you find it with very high probability in a pretty small region, but if you measure instead its momentum, the probability distribution for getting a certain momentum is very broad, i.e., it is very little known, which momentum you'll measure.agnick5 said:
I think this was first introduced by Einstein in his famous disputes with Bohr and other proponents of (the Copenhagen interpretation of) quantum theory. It describes the property that when two particles are prepared in an entangled state, it is impossible to consider them as separate individual entities, which manifests itself by these strong correlation when measuring their individual properties, which are very indetermined in such a state, at far distances.agnick5 said:
The problem is that this is a generally accepted answer only in a wide part of the physics community. Philosophers and some philosophy-inclined physicists think otherwise. They still consider QT in some sense incomplete, and that's why there's still this debate about the foundations of quantum theory is going on although from a physics point of view there are no problems, given that QT describes all observations correctly so far.agnick5 said: