English

Macroscopic Reality from Quantum Complexity

Quantum Physics 2022-05-23 v5 General Relativity and Quantum Cosmology History and Philosophy of Physics

Abstract

Beginning with the Everett-DeWitt many-worlds interpretation of quantum mechanics, there have been a series of proposals for how the state vector of a quantum system might split at any instant into orthogonal branches, each of which exhibits approximately classical behavior. Here we propose a decomposition of a state vector into branches by finding the minimum of a measure of the mean squared quantum complexity of the branches in the branch decomposition. In a non-relativistic formulation of this proposal, branching occurs repeatedly over time, with each branch splitting successively into further sub-branches among which the branch followed by the real world is chosen randomly according to the Born rule. In a Lorentz covariant version, the real world is a single random draw from the set of branches at asymptotically late time, restored to finite time by sequentially retracing the set of branching events implied by the late time choice. The complexity measure depends on a parameter bb with units of volume which sets the boundary between quantum and classical behavior. The value of bb is, in principle, accessible to experiment.

Keywords

Cite

@article{arxiv.2105.04545,
  title  = {Macroscopic Reality from Quantum Complexity},
  author = {Don Weingarten},
  journal= {arXiv preprint arXiv:2105.04545},
  year   = {2022}
}

Comments

101 pages, no figures, follow on to arXiv:1709.05777, arXiv:1802.10136, some overlap, mostly new, table of contents added to v5, changed to single column format

R2 v1 2026-06-24T01:57:29.888Z