Astrophysical properties of static black holes embedded in a Dehnen type dark matter halo with the presence of quintessential field

TL;DR

This paper investigates how dark matter halos with a quintessential field influence the properties of Schwarzschild black holes, including horizons, shadows, lensing, and quasinormal modes, revealing significant effects of the dark sector on observable phenomena.

Contribution

It provides a detailed analysis of black holes embedded in a Dehnen-type dark matter halo with quintessence, highlighting the impact of dark sector parameters on horizons, shadows, lensing, and gravitational wave signatures.

Findings

Dark sector parameters increase the event horizon size.

Dark sector parameters enlarge the black hole shadow.

Dark sector reduces the frequency and decay rate of gravitational waves.

Abstract

From an astrophysical perspective, the composition of black holes (BHs), dark matter (DM), and dark energy can be an intriguing physical system. In this study, we consider Schwarzschild BHs embedded in a Dehnen-type DM halo exhibiting a quintessential field. This study examines the horizons, shadows, deflection angle, and quasinormal modes (QNMs) of the effective BH spacetime and how they are affected by the dark sector. The Schwarzschild BH embodied in a Dehnen-type DM halo exhibiting a quintessential field possesses two horizons: the event horizon and the cosmological horizon. We demonstrate that all dark sector parameters increase the event horizon while decreasing the cosmological horizon. We analyze the BH shadow and emphasize the impact of DM and quintessence parameters on them. We show that the dark sector casts larger shadows than a Schwarzschild BH in a vacuum. Further, we delve into the weak gravitational lensing deflection angle using the Gauss-Bonnet theorem (GBT). We then investigate QNMs using the 6th order WKB approach. To visually underscore the dark sector parameters, we present figures that illustrate the impact of varying the parameters of the Dehnen-type DM halo as well as quintessence. Our findings show that the gravitational waves emitted from BHs with a dark sector have a lower frequency and decay rate compared to those emitted from BHs in a vacuum.