English

Time dispersion and quantum mechanics

Quantum Physics 2019-05-27 v2

Abstract

In quantum mechanics the time dimension is treated as a parameter, while the three space dimensions are treated as observables. This assumption is both untested and inconsistent with relativity. From dimensional analysis, we expect quantum effects along the time axis to be of order an attosecond. Such effects are not ruled out by current experiments. But they are large enough to be detected with current technology, if sufficiently specific predictions can be made. To supply such we use path integrals. The only change required is to generalize the usual three dimensional paths to four. We predict a large variety of testable effects. The principal effects are additional dispersion in time and full equivalence of the time/energy uncertainty principle to the space/momentum one. Additional effects include interference, diffraction, and entanglement in time. The usual ultraviolet divergences do not appear: they are suppressed by a combination of dispersion in time and entanglement in time. The approach here has no free parameters; it is therefore falsifiable. As it treats time and space with complete symmetry and does not suffer from the ultraviolet divergences, it may provide a useful starting point for attacks on quantum gravity.

Keywords

Cite

@article{arxiv.1812.00935,
  title  = {Time dispersion and quantum mechanics},
  author = {John Ashmead},
  journal= {arXiv preprint arXiv:1812.00935},
  year   = {2019}
}

Comments

Accepted by IOP Science Journal of Physics Conference Series for the International Association for Relativistic Dynamics (IARD) 2018 Conference. Revised from first version per suggestions by reviewers: includes additional references and clarifications of some ambiguities. Previously presented as a talk at the IARD 2018 Conference

R2 v1 2026-06-23T06:29:46.066Z