English

How a Space-Time Singularity Helps Remove the Ultraviolet Divergence Problem

Mathematical Physics 2025-11-25 v2 General Relativity and Quantum Cosmology math.MP Quantum Physics

Abstract

Particle creation terms in quantum Hamiltonians are usually ultraviolet divergent and thus mathematically ill defined. A rather novel way of solving this problem is based on imposing so-called interior-boundary conditions on the wave function. Previous papers showed that this approach works in the non-relativistic regime, but particle creation is mostly relevant in the relativistic case after all. In flat relativistic space-time (that is, neglecting gravity), the approach was previously found to work only for certain somewhat artificial cases. Here, as a way of taking gravity into account, we consider curved space-time, specifically the super-critical Reissner-Nordstr\"om space-time, which features a naked timelike singularity. We find that the interior-boundary approach works fully in this setting; in particular, we prove rigorously the existence of well-defined, self-adjoint Hamiltonians with particle creation at the singularity, based on interior-boundary conditions. We also non-rigorously analyze the asymptotic behavior of the Bohmian trajectories and construct the corresponding Bohm-Bell process of particle creation, motion, and annihilation. The upshot is that in quantum physics, a naked space-time singularity need not lead to a breakdown of physical laws, but on the contrary allows for boundary conditions governing what comes out of the singularity and thereby removing the ultraviolet divergence.

Keywords

Cite

@article{arxiv.2409.00677,
  title  = {How a Space-Time Singularity Helps Remove the Ultraviolet Divergence Problem},
  author = {Joscha Henheik and Bipul Poudyal and Roderich Tumulka},
  journal= {arXiv preprint arXiv:2409.00677},
  year   = {2025}
}

Comments

39 pages LaTeX; v2 minor revision, a mistake in Eq. (19) has been corrected

R2 v1 2026-06-28T18:30:28.600Z