Three-space from quantum mechanics
Abstract
The spin geometry theorem of Penrose is extended from to (Euclidean) invariant elementary quantum mechanical systems. Using the natural decomposition of the total angular momentum into its spin and orbital parts, the \emph{distance} between the centre-of-mass lines of the elementary subsystems of a classical composite system can be recovered from their \emph{relative orbital angular momenta} by -invariant classical observables. Motivated by this observation, an expression for the `empirical distance' between the elementary subsystems of a \emph{composite quantum mechanical system}, given in terms of -invariant quantum observables, is suggested. It is shown that, in the classical limit, this expression reproduces the \emph{a priori} Euclidean distance between the subsystems, though at the quantum level it has a discrete character. `Empirical' angles and 3-volume elements are also considered.
Cite
@article{arxiv.2203.04827,
title = {Three-space from quantum mechanics},
author = {László B. Szabados},
journal= {arXiv preprint arXiv:2203.04827},
year = {2022}
}
Comments
27 pages; v2: the whole paper rewritten, discussion improved, typos corrected, the uncertainty of the empirical distance also calculated, the key result strengthen and sharpen, references added; v3: references updated, typos corrected; v4: final version