English

Stable relativistic polytropic objects with cosmological constant

General Relativity and Quantum Cosmology 2020-04-15 v1

Abstract

The effects of the cosmological constant on the static equilibrium configurations and stability against small radial perturbations of relativistic polytropic spheres are investigated. This study numerically solves the hydrostatic equilibrium equation and the radial stability equation, both of which are modified from their standard form to introduce the cosmological constant. For the fluid, we consider a pressure pp and an energy density ρ\rho, which are connected through the equation of state p=κδΓp=\kappa\delta^{\Gamma} with δ=ρp/(Γ1)\delta=\rho-p/(\Gamma-1), where κ\kappa, Γ\Gamma and δ\delta represent the polytropic constant, adiabatic index and rest mass density of the fluid, respectively. The dependencies of the mass, radius and eigenfrequency of oscillations on both the cosmological constant and the adiabatic index are analyzed. For ranges of both the central rest mass density δc\delta_c and the adiabatic index Γ\Gamma, we show that the stars have a larger (lower) mass and radius and a diminished (enhanced) stability when the cosmological constant Λ>0\Lambda>0 (Λ<0\Lambda<0) is increased (decreased). In addition, in a sequence of compact objects with fixed Γ\Gamma and Λ\Lambda, the regions constructed by stable and unstable static equilibrium configurations are recognized by the conditions dM/dδc>0dM/d\delta_c>0 and dM/dδc<0dM/d\delta_c<0, respectively.

Keywords

Cite

@article{arxiv.2004.06604,
  title  = {Stable relativistic polytropic objects with cosmological constant},
  author = {José D. V. Arbañil and Pedro H. R. S. Moraes},
  journal= {arXiv preprint arXiv:2004.06604},
  year   = {2020}
}

Comments

11 pages, 7 figures

R2 v1 2026-06-23T14:51:01.035Z