# Extra dimensions' influence on the equilibrium and radial stability of   strange quark stars

**Authors:** Jos\'e D. V. Arba\~nil, Geanderson A. Carvalho, Ronaldo V. Lobato,, Rubens M. Marinho Jr., Manuel Malheiro

arXiv: 1907.07661 · 2019-07-18

## TL;DR

This study explores how extra spatial dimensions affect the structure and stability of strange quark stars, revealing that higher dimensions can enhance stability and alter key physical parameters.

## Contribution

It extends stellar structure and stability analysis to higher-dimensional spacetimes using a modified MIT bag model and Schwarzschild-Tangherlini metric.

## Key findings

- Higher dimensions increase the stability range of strange quark stars.
- Maximum mass and oscillation eigenfrequency are linked at the onset of instability.
- Stability criteria depend on the derivative of mass with respect to central density.

## Abstract

We analyze the influence of extra dimensions on the static equilibrium configurations and stability against radial perturbations. For this purpose, we solve stellar structure equations and radial perturbation equations, both modified for a $d$-dimensional spacetime ($d\geq4$) considering that spacetime outside the object is described by a Schwarzschild-Tangherlini metric. These equations are integrated considering a MIT bag model equation of state extended for $d\geq4$. We show that the spacetime dimension influences both the structure and stability of compact objects. For an interval of central energy densities $\rho_{cd}\,G_d$ and total masses $MG_d/(d-3)$, we show that the stars gain more stability when the dimension is increased. In addition, the maximum value of $M{G_d}/(d-3)$ and the zero eigenfrequency of oscillation are found with the same value of $\rho_{cd}\,G_d$; i.e., the peak value of $M{G_d}/(d-3)$ marks the onset of instability. This indicates that the necessary and sufficient conditions to recognize regions constructed by stable and unstable equilibrium configurations against radial perturbations are, respectively, $dM/d\rho_{cd}>0$ and $dM/d\rho_{cd}<0$. We obtain that some physical parameter of the compact object in a $d$-dimensional spacetime, such as the radius and the mass, depend of the normalization. Finally, within the Newtonian framework, the results show that compact objects with adiabatic index $\Gamma_1\geq2(d-2)/(d-1)$ are stable against small radial perturbations.

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1907.07661/full.md

## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1907.07661/full.md

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Source: https://tomesphere.com/paper/1907.07661