# Dark compact objects: an extensive overview

**Authors:** Maksym Deliyergiyev, Antonino Del Popolo, Laura Tolos, Morgan Le, Delliou, Xiguo Lee, and Fiorella Burgio

arXiv: 1903.01183 · 2019-05-15

## TL;DR

This paper investigates the structure of dark matter-admixed compact objects, analyzing how dark matter particle mass and interaction strength influence their mass and properties, providing constraints on dark matter characteristics.

## Contribution

It extends previous models by exploring a wider range of dark matter particle masses and interaction strengths, deriving new constraints on dark matter properties within compact objects.

## Key findings

- Mass increases as dark matter particle mass decreases.
- Strongly interacting dark matter with 1-10 GeV mass leads to masses exceeding neutron star limits.
- Constraints on dark matter particle mass and interaction strength are derived from observed compact object masses.

## Abstract

We study the structure of compact objects that contain non-self annihilating, self-interacting dark matter admixed with ordinary matter made of neutron star and white dwarf materials. We extend the previous work Phys. Rev. D 92 123002 (2015) on these dark compact objects by analyzing the effect of weak and strongly interacting dark matter with particle masses in the range of 1-500 GeV, so as to set some constraints in the strength of the interaction and the mass of the dark matter particle. We find that the total mass of the compact objects increases with decreasing dark matter particle mass. In the strong interacting case and for dark matter particle masses in the range 1-10 GeV, the total mass of the compact objects largely exceeds the $2M_\odot$ constraint for neutron star masses and the nominal $1M_\odot$for white dwarfs, while for larger dark matter particle masses or in the weakly interacting case the compact objects show masses in agreement or smaller than these constraints, thus hinting at the exclusion of strongly self-interacting dark matter of masses 1-10 GeV in the interior of these compact objects. Moreover, we observe that the smaller the dark matter particle mass, the larger the quantity of dark matter captured is, putting constraints on the dark matter mass trapped in the compact objects so as to fullfill $\simeq 2M_\odot$ observations. Finally, the inhomogeneity of distribution of dark matter in the Galaxy implies a mass dependence of compact objects from the environment which can be used to put constraints on the characteristics of the Galaxy halo DM profile and on particle mass. In view of the these results, we discuss the formation of the dark compact objects in an homogeneous and non-homogeneous dark matter environment.

## Full text

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## Figures

21 figures with captions in the complete paper: https://tomesphere.com/paper/1903.01183/full.md

## References

86 references — full list in the complete paper: https://tomesphere.com/paper/1903.01183/full.md

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Source: https://tomesphere.com/paper/1903.01183