English

How Classical Particles Emerge From the Quantum World

Quantum Physics 2011-05-23 v1

Abstract

The symmetrization postulates of quantum mechanics (symmetry for bosons, antisymmetry for fermions) are usually taken to entail that \emph{quantum particles} of the same kind (e.g., electrons) are all in exactly the same state and therefore indistinguishable in the strongest possible sense. These symmetrization postulates possess a general validity that survives the classical limit, and the conclusion seems therefore unavoidable that even classical particles of the same kind must all be in the same state--in clear conflict with what we know about classical particles. In this article we analyze the origin of this paradox. We shall argue that in the classical limit classical particles \emph{emerge}, as new entities that do not correspond to the "particle indices" defined in quantum mechanics. Put differently, we show that the quantum mechanical symmetrization postulates do not pertain to \emph{particles}, as we know them from classical physics, but rather to indices that have a merely formal significance. This conclusion raises the question of whether the discussions about the status of identical quantum particles have not been misguided from the very start.

Keywords

Cite

@article{arxiv.1002.2544,
  title  = {How Classical Particles Emerge From the Quantum World},
  author = {Dennis Dieks and Andrea Lubberdink},
  journal= {arXiv preprint arXiv:1002.2544},
  year   = {2011}
}
R2 v1 2026-06-21T14:46:26.874Z