English

One-Loop quantum gravity in the Einstein universe

High Energy Physics - Theory 2017-03-01 v2 General Relativity and Quantum Cosmology Mathematical Physics math.MP

Abstract

We study quantum gravity with the Einstein-Hilbert action including the cosmological constant on the Euclidean Einstein universe S1×S3S^1\times S^3. We compute exactly the spectra and the heat kernels of the relevant operators on S3S^3 and use these results to compute the heat trace of the graviton and ghost operators and the exact one-loop effective action on S1×S3S^1\times S^3. We show that the system is unstable in the infrared limit due to the presence of the negative modes of the graviton and the ghost operators. We study the thermal properties of the model with the temperature T=(2πa1)1T=(2\pi a_1)^{-1} determined by the radius a1a_1 of the circle S1S^1. We show that the heat capacity CvC_v is well defined and behaves like T3\sim T^3 in the high temperature limit and has a singularity of the type (TTc)1\sim (T-T_c)^{-1}, indicating a second-order phase transition, with the critical temperature TcT_c determined by the cosmological constant Λ\Lambda and the radius aa of the sphere S3S^3. We also discuss some peculiar properties of the model such as the negative heat capacity as well as possible physical applications.

Keywords

Cite

@article{arxiv.1509.00929,
  title  = {One-Loop quantum gravity in the Einstein universe},
  author = {Ivan G. Avramidi and Samuel J. Collopy},
  journal= {arXiv preprint arXiv:1509.00929},
  year   = {2017}
}

Comments

50 pages, 2 figures; misprints in eqs. (5.114), (5.115), (5.181), (5.186), (5.187) corrected; final results not affected

R2 v1 2026-06-22T10:48:00.958Z