English

Quantum gravity effects on compact star cores

General Relativity and Quantum Cosmology 2015-05-30 v2 High Energy Physics - Theory

Abstract

Using the Tolman-Oppenheimer-Volkoff equation and the equation of state of zero temperature ultra-relativistic Fermi gas based on generalized uncertainty principle (GUP), the quantum gravitational effects on the cores of compact stars are discussed. Our results show that 2m(r)/r{2m(r)}/ {r} varies with rr. Quantum gravity plays an important role in the region r103r0 r\sim 10^3 r_0, where r0β0lpr_0\sim \beta_0 l_p , lpl_p is the Planck length and β0\beta_0 is a dimensionless parameter accounting for quantum gravity effects. Furthermore, near the center of compact stars, we find that the metric components are gttr4g_{tt}\sim r^4 and grr=[1r2/(6r02)]1g_{rr}=[1-{r}^2/(6r_0^2)]^{-1}. All these effects are different from those obtained from classical gravity. These results can be applied to neutron stars or denser ones like quark stars. The observed masses of neutron stars (2M\leq 2M_\odot) indicate that β0\beta_0 can not exceed 103710^{37}, not as good as the upper bound β0<1034\beta_0<10^{34} from simple electroweak consideration. This means that incorporating either quantum gravity effects or nuclear interactions, one obtains almost the same mass limits of neutron stars.

Keywords

Cite

@article{arxiv.1110.5550,
  title  = {Quantum gravity effects on compact star cores},
  author = {Peng Wang and Haitang Yang and Xiuming Zhang},
  journal= {arXiv preprint arXiv:1110.5550},
  year   = {2015}
}

Comments

12 pages, 1 figure, added brief review on compact stars configurations, abstract expanded, references added, typo corrected, published version

R2 v1 2026-06-21T19:25:25.813Z