vanhees71 said:I'd say we have understood a phenomenon if our theories agree with the observations. I don't know what else you mean by "understanding".
vanhees71 said:I don't understand what you are referring to when you say the conservation laws hold only on average. According to standard Q(F)T angular momentum is conserved, and it's conserved on an event-by-event basis. I'm not aware of any observation disproving this.
Agreed.RUTA said:The mystery resides in the desire for a causal mechanism responsible for those correlations
Maybe this part of the question is where it goes wrong? Is the question wrong and there is no answer, or didn't anyone just find the answer yet?RUTA said:...and that is assumed to function per the causal structure of M4 per "local realism." No one has that answer.
Agreed here as well.RUTA said:Exactly, that's the mystery. So, the various interpretations propose various causal mechanisms that violate local realism in various ways to account for the correlations. Then the proponents of a given interpretation argue why they think the manner by which their interpretation violates local realism makes sense. So far, no one has produced an interpretation that has garnered consensus support.
I disagree. The mystery resides in the quasi-religious status of the thesis that relativistic symmetry is fundamental and not simply emergent. Relativity has to be about space and time because we are so clever that we are able to understand very fundamental properties of space and time.RUTA said:The mystery resides in the desire for a causal mechanism responsible for those correlations and that is assumed to function per the causal structure of M4 per "local realism." No one has that answer.
The formalism works, because it is based on observations. That's how the scientific method successfully works since Galilei et al.RUTA said:That is why you don't understand the mystery and you keep posting, "The formalism works, what else do you want?" For those who want to know why the formalism works, you have provided nothing.
Tachyons are compatible with SR and are part of many speculative theories that are routinely published in peer-reviewed journal as there are many publications about speculative quantum gravity theories or time travel theories(which also informs about the the quality decay of modern day journals), but they are not so far compatible with QFT or the Standard model, once again due to problems with causality and coherence with any physical scientific theory that arise when admitting FTL communication,(it might surprise you but FTL signaling is not considered a good thing for a theory, go figure). So it is perfectly sensible to leave those speculative entities outside a serious discussion about quantum theories without having to collect the massive bibliography about it. You can google tachyon as easily as anyone if you need a quick access to such references.PeterDonis said:Sure. My experiment was one-way.
Aren't you ignoring the fact that the correlations observed(in quantum experiments) are not compatible with classical, pre-relativistic time correlations?Sunil said:I disagree. The mystery resides in the quasi-religious status of the thesis that relativistic symmetry is fundamental and not simply emergent. Relativity has to be about space and time because we are so clever that we are able to understand very fundamental properties of space and time.
Instead, emergent relativity would leave us with boring distortions of clocks and rulers which play no fundamental role at all, and the difference to the Newtonian world is that with those distorted rulers and clocks we have no chance to measure space and time distances accurately. This picture of the world is boring, not mysterious. But physicists like mystery - this is what has fascinated them when they have, in impressive childhood years, looked at popular descriptions of relativity.
To preserve classical causality as it was in pre-relativistic time has also nothing to do with mystery. The Goedel universe or wormholes are much better candidates for those who love mysticism.
The answer is well-known, but rejected because it means a return to quite old, boring metaphysics, and requires the rejection of mysticism.
Perhaps we are talking about different things? Perhaps it was my flawed interpretation and i don't get what you guys are talking about. I thought RUTA meant that the "open issue" (mystery, is just a word?) is to to find an explanation of the correlations observed in entanglement. And if possible an explanation that obeys local realism. I think explanations are possible, but they the premises in "local realism" is wrong to start with. Nevertheless, and "explanation" is wanted.Sunil said:To preserve classical causality as it was in pre-relativistic time has also nothing to do with mystery.
vanhees71 said:I don't know what "local realism" is, because I don't know of any clear definition of "realism", and about "locality" we have a lot of debates here.
I agree that just these definitions of these terms drives a lot of the discussions on their own.vanhees71 said:I don't know what "local realism" is, because I don't know of any clear definition of "realism", and about "locality" we have a lot of debates here.
But it seems even the attempts at precise definitions, become dependent on interpretations. For example, for some of us, the notion of "existing independent of observation" is just a metaphysical notions. This is why for me; the closest thing to realism lies in say the "invariants" of the symmetries in the observer classes. But such definitions presumes the existence of such symmetry transformations. To defined something as independent of observation, means its not inferrable, and to me that is a no no.Lord Jestocost said:“Most working scientists hold fast to the concept of 'realism' - a viewpoint according to which an external reality exists independent of observation. But quantum physics has shattered some of our cornerstone beliefs…..
Sunil said:The answer is well-known
vanhees71 said:The formalism works, because it is based on observations. That's how the scientific method successfully works since Galilei et al.
Tendex said:they are not so far compatible with QFT or the Standard model, once again due to problems with causality and coherence with any physical scientific theory that arise when admitting FTL communication
Tendex said:if it is one-way, how would you tell that the particle detected first is not the light signal, and therefore no FTL?
Tendex said:You have to have some synchronization convention for the times at departure and detection, no?
Such a detector would allow to measure the speed of light in a one-way experiment then.PeterDonis said:Because you have two different kinds of detectors, one that only detects light signals and one that only detects whatever postulated FTL signal carrier you are using.
I'm referring to the simultaneity convention between emission and detection in view of what I say above about detectors.No. Both departure events are the same event--both emission devices are co-located in space and emit their signals at the same instant.
Both detection events are on the same timelike worldline, since the detectors are also co-located in space and are at rest relative to each other. So the time ordering of the detection events is invariant and does not require any simultaneity convention.
The test is of course not impossible if you are willing to consider galilean relativity or Lorent ether theory or some version of Bohmian mechanics and the like as some people in this very thread. According to QFT the result is always going to be negative, that's for sure. Scientific experiments are usually done to discard one theory versus some other. If one does detect such FTL influences it is up to the experimenter to decide whether this means special relativistic theories are wrong and recover Galilean ones, or interpret it as relativistic QFT must admit a breakup of causality, the last option is more problematic as it means breaking with all scientific knowledge based on causality including the rationale of being able to make predictions besides creating contradiction with the way QFT is constructed.Bear in mind, I am not saying anyone actually has an FTL signaling device that could pass the test I'm describing. I'm just saying that testing whether a device that is claimed to do FTL signaling, actually does it, is a straightforward experimental test and does not require having any particular theory about how FTL signaling works or how it should not be possible. Of course our current theories of relativity and QFT predict that it is not possible and any such test would fail. But that does not make the test itself impossible or not well-defined.
Tendex said:Such a detector would allow to measure the speed of light in a one-way experiment then.
Tendex said:I'm referring to the simultaneity convention between emission and detection in view of what I say above about detectors.
Tendex said:The test is of course not impossible if you are willing to consider galilean relativity or Lorent ether theory or some version of Bohmian mechanics and the like as some people in this very thread.
There is no such fact. The realist interpretations need an absolute time (that means a hidden preferred frame) but have no causal influences into the past. So, they follow the same type of causal restrictions as in classical physics.Tendex said:Aren't you ignoring the fact that the correlations observed(in quantum experiments) are not compatible with classical, pre-relativistic time correlations?
What I name mysticism is the rejection of principles and concepts of common sense without necessity.Fra said:Perhaps we are talking about different things? Perhaps it was my flawed interpretation and i don't get what you guys are talking about. I thought RUTA meant that the "open issue" (mystery, is just a word?) is to to find an explanation of the correlations observed in entanglement. And if possible an explanation that obeys local realism. I think explanations are possible, but they the premises in "local realism" is wrong to start with. Nevertheless, and "explanation" is wanted.
We know QM works, but as long as we do not understand it properly, its explanatory value is limited.
This I agree with. I see no mysticism here?
Let's start with the classical theory of sound waves, with the equation ##\square u = (\frac{1}{c^2}\partial_t^2 - \Delta) u = 0##, with the speed of the wave being c. It is simple mathematics to see that the Lorentz transformation with that c of a solution of that equation gives the Doppler-shifted solution of the same equation. So, the equation has Lorentz symmetry. And it is emergent because there is no such Lorentz symmetry on the atomic level.PeterDonis said:Really? Someone has a well-tested, experimentally confirmed theory in which Lorentz invariance is not fundamental, but emergent? Please provide a reference.
I see.Sunil said:What I name mysticism is the rejection of principles and concepts of common sense without necessity.
Ok, at least i know what you mean. For me however, "common sense" does not equal classical physics. Some things suggested by quantum mechanics, for example that that action of agents are causally determined by its subjective probability, rather than hidden variable, is MORE SENSIBLE than classical physics. I have been giving this a lot of considerations over time, and although before my first QM course, I admitt that I had also another view. But this is revised, and common sense today means something else for me.Sunil said:the principles of common sense, as known from classical physics.
..
The rejection of classical elements of explanation, like causal explanations for observed correlations, is standard part of mystical theories.
Sunil said:Let's start with the classical theory of sound waves, with the equation ##\square u = (\frac{1}{c^2}\partial_t^2 - \Delta) u = 0##, with the speed of the wave being c.
Sunil said:Schmelzer, I. (2012). A Generalization of the Lorentz Ether to Gravity with General-Relativistic Limit. Advances in Applied Clifford Algebras 22(1), 203-242, resp. arxiv:gr-qc/0205035
The equation is, of course, for a homogeneous medium in its rest frame. Real media are inhomogeneous, so that this is only an approximation. But this is not in contradiction with Lorentz invariance of the equation. You can use Galiean transformation in SR too, and you will also obtain a different equation.PeterDonis said:The equation you give is indeed Lorentz invariant, but it is not "the classical theory of sound waves". The classical theory of sound waves predicts, correctly, that the speed of sound waves is different in a frame in which the medium in which the waves are propagating is moving than it is in a frame in which the medium is at rest. The equation you wrote does not predict that.
I have tried to find something, but probably used wrong search items given that I have found almost nothing.PeterDonis said:You will find plenty of previous discussions of Schmelzer's work here on PF. The fact that the GR limit of this theory is well-tested, since GR itself is well-tested, does not mean the theory as a whole is well tested. To test the theory itself would require testing in a regime where its predictions differ from GR. No such testing has been done.
The fact is that the probabilities obtained in quantum experiments can never be achieved by classical correlations(whatever hidden varaibles are used including preferred frame with distorted clocks and rulers), so how come there is no such fact?Sunil said:There is no such fact. The realist interpretations need an absolute time (that means a hidden preferred frame) but have no causal influences into the past. So, they follow the same type of causal restrictions as in classical physics.
Sunil said:I have tried to find something, but probably used wrong search items given that I have found almost nothing.
I disagree with your idea about testing. One should not use a historical accident of which theory was proposed earlier to evaluate their experimental support. All what counts is what both theories predict, and if this agrees with observation. From this point of view, this theory is as well tested as GR.
BTW, it is not my point that the theory is well-tested. The point is that there is an interpretation of modern physics compatible with common sense, without any trace of mysticism. As for the quantum domain, as for the relativistic domain, and both being compatible with each other.
Well first you are assuming certain things before the experiment, you seem to be discarding spacelike paths since, for all we have discussed before about setting up a scenario to observe a causal, timelike order of arrival of signals if causality is not granted and you can have signals detected before being emitted, etc, order is inmaterial in the spacelike case and you claim to only be testing an order. So you are considering only timelike, causal paths.PeterDonis said:Not without a simultaneity convention. Remember, all that is being "measured" in my scenario is the time order of the two arrivals--light signal vs. claimed "FTL" signal. In my scenario, the speed of the signals is not being measured; only in which order they arrive. That very limited measurement does not require a simultaneity convention, while a measurement of speed would.
No such convention is required for the very limited measurement I am describing. See above.
The test I have described, as I have already said, does not require having or adopting any theory at all. It is a purely empirical measurement of a very limited result, the order in which two signals arrive.
Ok, I also take some modern interpretations of classical physics, like the objective Bayesian interpretation of probability (Jaynes) and their reinterpretation of thermodynamics so that entropy is a measure of information about a state and not of the state itself, also as more compatible with common sense.Fra said:Ok, at least i know what you mean. For me however, "common sense" does not equal classical physics. Some things suggested by quantum mechanics, for example that that action of agents are causally determined by its subjective probability, rather than hidden variable, is MORE SENSIBLE than classical physics.
Yes, but this is the sort of problem to be left to future research. Already Newton himself has not liked this aspect of his theory, but he had to leave it to future research. Same situation now with the quantum non-locality. One can leave it to future research to find some theory with some limiting speed for that quantum non-locality too. That such a local replacement of QT cannot be Einstein-local is clear. I'm not sure if the experimental limit of ##> 10^4 c## has been improved by recent Bell tests or not. But I agree that some local theory with much larger limiting speed would be preferable from point of view of common sense.Fra said:I also consider, if anything, that influences on actions are not instant to be very common sense. In this sense, Newtons physics is not very sensible at all.
But all the common sense principles are also candidate principles for fundamental theories. Once a problem is to unify QT and RT, then finding interpretations of both compatible with the same common sense principles already gives a common set of principles for both theories, which defines a guiding rule for a unification.Fra said:Regarding necessity, for me, that is not rooted in "interpretations only", the necessity is rooted in trying to understand the open questions in physics. Such as unifying forces and QM and gravity etc. And when thinking about what for quite some time, I have come to the conclusion that this problem is entangled with the foundational problems of QM. This is the motivation for my "necessity".
Reinterpretations, that make no ambition to the open problems however, is in my eyes unneccessary, or are constrained to ease of mind only.
First, I would recommend you to learn how to behave in a scientific discussion. Then, if you think you can do this in "infinitely many ways", feel free to prove it by publishing papers in this way. We live in "publish or perish" times, not? So, this would be a chance for you to learn how to get (not) published.martinbn said:This, and the paper are stupid. The theory goes like this: add new terms with new parameters to the lagrangian of the old theory and you get a new theory which coincides with the old when the parameters are equal to zero. Then take credit for all the successes of the old theory without any new prediction tested by observation. Then add your preferred philosophical mumbo jumbo that supports your prejudices on how nature should be and write a paper. Anyone can do this in an infinitely many ways. How can this be used as an argument against the old theory!
Of course, the trajectories of dBB theory differ from classical trajectories. But what would be the point of this, if we nonetheless have to same classical configuration space describing reality? The quantum equations are equations quite similar to classical equations, so that the difference is not that big.Tendex said:The fact is that the probabilities obtained in quantum experiments can never be achieved by classical correlations(whatever hidden varaibles are used including preferred frame with distorted clocks and rulers), so how come there is no such fact?
Yes, I'm completely missing your point about correlations. If you have in mind violations of the Bell inequalities, they can be easily obtained in a classical scenario if the measurement on one side causally influences the state of the other side.Tendex said:Also in any scientific theory they are going to follow the same type of causal restrictions, this is a pre-requisite for making sense of observations and making predictions that can be checked by later observations so you must be missing my point about correlations.
I'm not following your answer, here is where I had in mind BI violations.Sunil said:Of course, the trajectories of dBB theory differ from classical trajectories. But what would be the point of this, if we nonetheless have to same classical configuration space describing reality? The quantum equations are equations quite similar to classical equations, so that the difference is not that big.
In classical theory with just Galilean relativity FTL influences are no big deal and don't affect causality in any way since the speed of light is not a maximum,so they shouldn't require a theory that constructs probabilities in a different way than the classical real probabilities, however quantum theory does require it to obtain better predictions.Sunil said:Yes, I'm completely missing your point about correlations. If you have in mind violations of the Bell inequalities, they can be easily obtained in a classical scenario if the measurement on one side causally influences the state of the other side.
The causal restrictions of classical theory and relativistic theory are quite different, in classical theory FTL causal influences are not forbidden, in relativity they are forbidden.
If this is understood as physical realism, I don't understand, why quantum physics "questions this concept in a very deep way." The only thing that quantum physics disproves is determinism, which is just the concept of classical physics. QT indeed discribes "properties carried by physical systems", and one property is that these properties are not describable by a deterministic theory but that there is inherent randomness. What's "real" in this simple sense is described in QT by the states, whose meaning and only meaning is to give the probabilities for the outcome of measurements made on a system prepared in a specific state. One must just forget about the classical picture of determinism, and there's no quibble anymore!Lord Jestocost said:That's relatively simple. As Simon Gröblacher, Tomasz Paterek, Rainer Kaltenbaek, Caslav Brukner, Marek Zukowski, Markus Aspelmeyer and Anton Zeilinger put it in “An experimental test of non-local realism” ( Nature, vol. 446, pages 871–875 (2007))
“Most working scientists hold fast to the concept of 'realism' - a viewpoint according to which an external reality exists independent of observation. But quantum physics has shattered some of our cornerstone beliefs…..
Physical realism suggests that the results of observations are a consequence of properties carried by physical systems. It remains surprising that this tenet is very little challenged, as its significance goes far beyond science. Quantum physics, however, questions this concept in a very deep way. To maintain a realistic description of nature, non-local hidden-variable theories are being discussed as a possible completion of quantum theory.”
The point is that there is no mystery. It's just an outcome of our investigations in physics that nature is not deterministic but has to be described by a probabilistic theory named QT. That the formalism maps so well to the observations is not trivial, as you seem to suggest. It's just amazing, in how simple a way we can describe almost everything with a mathematical theory, but to find such a description is only possible through observations and finding (with some luck ;-)) the right mathematical model to describe them with a quite sparse set of fundamental "postulates". If there is any mystery, it's the question, why these mathematical descriptions work so well, as was famously asked by Wigner.RUTA said:The articulation of the mystery: "What is the nature of reality/causal mechanism such that the formalism maps so well to the experimental outcomes?"
Your response: "The formalism maps so well to the outcomes because the formalism maps so well to the outcomes."
Do you understand that your response provides absolutely nothing for resolving the mystery? I can't make it any clearer than that.
RUTA said:The articulation of the mystery: "What is the nature of reality/causal mechanism such that the formalism maps so well to the experimental outcomes?"
Your response: "The formalism maps so well to the outcomes because the formalism maps so well to the outcomes."
Do you understand that your response provides absolutely nothing for resolving the mystery? I can't make it any clearer than that.
I can share this statement and but probably unlike Wigner, I think the question is sensible. I suspect Wigner puts it as a rethorical question.vanhees71 said:If there is any mystery, it's the question, why these mathematical descriptions work so well, as was famously asked by Wigner.
Sunil said:The equation is, of course, for a homogeneous medium in its rest frame.
Sunil said:this is not in contradiction with Lorentz invariance of the equation
Sunil said:it is not my point that the theory is well-tested. The point is that there is an interpretation of modern physics compatible with common sense
Sunil said:If you have in mind violations of the Bell inequalities, they can be easily obtained in a classical scenario if the measurement on one side causally influences the state of the other side.
Sunil said:First, I would recommend you to learn how to behave in a scientific discussion.