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Moderator's Note: Thread spun off from previous thread due to topic change.
But for those who take such infinite sets seriously and love stuff such as functional analysis and axiomatic QFT, I would mention the Reeh-Schlieder theorem. It seems that this theorem is a rigorous expression of a Bell-like nonlocality in axiomatic QFT.
I see. Basically you are worried by stuff a mathematical physicist would study with fancy schmancy functional analysis. I'm not worried too much by such stuff because I don't think that actual infinities (actually infinite number of degrees of freedom, actually infinite dimensional Hilbert space) exist in the real world. Actual infinities are just idealizations that make some analytic calculations easier. When calculations with infinite sets become harder than those with big finite sets, then it's time to return to big finite sets.A. Neumaier said:Bell nonlocality is derived solely by proving that Schrödinger picture quantum mechanics in a finite-dimensional Hilbert space predicts violations of Bell inequalities. No quantum optics or quantum field theory is involved at all, not even relativity. Interacting relativistic QFT has not even a consistent particle picture at finite times. Hence there is a large gap between QFT and Bell nonlocality.
But for those who take such infinite sets seriously and love stuff such as functional analysis and axiomatic QFT, I would mention the Reeh-Schlieder theorem. It seems that this theorem is a rigorous expression of a Bell-like nonlocality in axiomatic QFT.