Demystifier said:
Why not non-local? After all, the good old Newton theory of gravity is also non-local. True, in 1920 there is also a better relativistic local theory of gravity, but it is not yet so rigidly encoded in physicists minds to prevent thinking in old Newtonian terms.martinbn said:
Demystifier said:
Thanks but both approaches skip/ignore/bypass (like you have in this thread, not surprisingly since you are a declared Bohmian) the measurability problem coming from the intrinsic quantum uncertainty that I raised, considering it trivial or nonimportant, or simply due to interactions as if that explained anything(it's like saying that the measurement problem is due to measurements, true but hardly useful).Demystifier said:
So, do you have a better explanation? Or do you think it's still an open problem?RockyMarciano said:
Sure, but they would have various working hypothesis, and some of them would be more popular than others. What would be the most popular ones?martinbn said:
Demystifier said:
It's an open problem AFAICS, but I'm intrigued about what I see as a neglected angle of the problem, the stability of measurements despite the intrinsic uncertainty in QM. Curiously something similar happens in relativity where perfectly solid rods are impossible and prevent the existence of stable measuring rods in principle. I found a parallelism with your assertion about dynamics(measurements are considered dynamical) and conservation being incompatible.Demystifier said:
I don't follow you. Why are you saying that the solution provided by BM (a random initial "position/hidden variable" distribution) should be called a "neglected problem". Actually the determinism bundled into BM kind of guaranteed that it may be testable. Until then, it is just another interpretation.RockyMarciano said:
Here also, solid rod aren't prevented by relativity. Perfectly solid rod are prevented by Nature (whatever that word is supposed to mean (within very misguided intuition)) and explained more by accoustic/mechanic/chemical theories than relativity.RockyMarciano said:
Well, there's progress in science. All the people dealing with the problems of "quantum phenomena" in the years 1920-1925 were well aware that their semiclassical patchwork models were just this, and they were vigorously looking for a consistent description, leading to modern QT. Why should we bother with these quibbles today anymore? It's interesting for the history of science and it's good to know about how the modern theories (and also classical physics by the way) came about to understand the meaning of the modern theory better, but to answer foundational questions you should answer them with the most recent theories we have. The point is that the standard QFT solved all these apparent problems (at least for a physicist interested in phenomenology). The true fundamental problems of modern relativistic QFT are not in these philosophical issues but in the mathematics which are still not completely solved.Demystifier said:
Good point! But some of us are interested in more than phenomenology.vanhees71 said:
And how would non-local correlations be explained by local hidden variables?martinbn said:
Yes, and then you leave the realm of the natural science ;-)). At best you do mathematics then, at worst...Demystifier said:
... I do something I like, publish it in Foundations of Physics, and get payed for that by tax payers.vanhees71 said:
.I slipped this. Mathematically there is for all our physical models measurements, actually. It is implied by things like metrics, norms, inner products, unitarity, isometries ...and involved in the dynamics. Matching this to randomness and uncertainty which is the opposite of these symmetries is the puzzle I guess.Demystifier said:
Yes, and indeed the idea to just define the metre by a platinum stick in Paris, is not stable enough. That's why for more than 50 years the metre is defined via natural fundamental constants (or at least what we believe are such quantities according to our contemporary models).Demystifier said:
Well, the kind or research I do is neither phenomenology nor mathematical physics. It is foundations of physics. I like to define it as dealing with philosophical questions by using methodology of theoretical sciences (theoretical physics, mathematics and logic).vanhees71 said:Well, you are still on the good side of mathematical physics, and I think here the tax-payers' money is well spent
Even according to our current models those constants are not so fundamental in the sense of stable, they are "running" constants.vanhees71 said:
I thought you were referring to constants like the fine structure constant, and you surely know about "running constants" in QFT.vanhees71 said:
"Running constants" do not run just because time passes. Running constants are just a convenient way to describe the fact that directly measurable quantities (like scattering cross sections) depend on energy.RockyMarciano said:
Exactly, therefore their stability upon measurement is not complete and as you say depends on energy. This is my point.Demystifier said:
I still don't understand what is your main point behind all your posts about stability and measurement.RockyMarciano said:
In QT as you now seem to acknowledge(in spite of your demonstrations on the contrary in #106) measurements are not completely stable, uncertainty and coupling constants are constantly adjusted to the relevant energy because of "the fact that directly measurable quantities (like scattering cross sections) depend on energy", my main point was this and also of puzzlement that even with this lack of stability measurements are possible and consistent, and we can matematically model idealized measuring tools that are conserved(intervals, inner products, etc).Demystifier said:I still don't understand what is your main point behind all your posts about stability and measurement.
So they are not completely stable, but they are quite stable. Isn't that enough for most practical purposes?RockyMarciano said:
Demystifier said:
vanhees71 said:
But Bell theorem, that certain type of correlations cannot be explained by local hidden variables, does not depend on knowledge of quantum mechanics. A good probability theorist could have derived it in the 19th century. One of Bell's points is precisely that such correlations are not like matching socks.martinbn said: