English

Accelerated Particle Detectors with Modified Dispersion Relations

High Energy Physics - Theory 2023-08-29 v1

Abstract

There is increasing interest in discrete or "pixelated" spacetime models as a foundation for a satisfactory theory of quantum gravity. If spacetime possesses a cellular structure, there should be observable consequences: for example, the vacuum becomes a dispersive medium. Of obvious interest are the implications for the thermodynamic properties of quantum black holes. As a first step to investigating that topic, we present here a calculation of the response of a uniformly accelerating particle detector in the (modified) quantum vacuum of a background pixelated spacetime, which is well known to mimic some features of the Hawking effect. To investigate the detector response we use the standard DeWitt treatment, with a two-point function modified to incorporate the dispersion. We use dispersion relations taken from the so-called doubly special relativity (DSR) and Ho\v{r}ava-Lifshitz gravity. We find that the correction terms retain the Planckian nature of particle detection, but only for propagation faster than the speed of light, a possibility that arises in this treatment because the dispersion relations violate Lorentz invariance. A fully Lorentz-invariant theory requires additional features; however, we believe the thermal response will be preserved in the more elaborate treatment.

Keywords

Cite

@article{arxiv.2307.14977,
  title  = {Accelerated Particle Detectors with Modified Dispersion Relations},
  author = {Paul C. W. Davies and Philip Tee},
  journal= {arXiv preprint arXiv:2307.14977},
  year   = {2023}
}

Comments

Acceptted paper in Physical Review D, DOI to come

R2 v1 2026-06-28T11:42:02.143Z