Shadow, ISCO, Quasinormal modes, Hawking spectrum, Weak Gravitational lensing, and parameter estimation of a Schwarzschild Black Hole Surrounded by a Dehnen Type Dark Matter Halo

TL;DR

This paper investigates the effects of a Dehnen-type dark matter halo on a Schwarzschild black hole, analyzing horizon, photon orbits, ISCO, shadows, quasinormal modes, Hawking radiation, gravitational lensing, and observational bounds.

Contribution

It introduces a comprehensive model of a Schwarzschild black hole embedded in a Dehnen dark matter halo, exploring its impact on various physical phenomena and observational signatures.

Findings

Dark matter increases photon orbit and shadow sizes.

Core density and radius significantly affect quasinormal modes.

Model aligns with observational bounds from EHT, Keck, and VLTI.

Abstract

We consider \s black hole (BH) embedded in a Dehnen-$(1,4,0)$ type dark matter halo (DDM) with two additional parameters - core radius $r_s$ and core density $\rs$ apart from mass $M$. We analyze the event horizon, photon orbits, and ISCO around DDM BHs and emphasize the impact of DDM parameters on them. Our study reveals that the presence of dark matter (DM) favourably impacts the radii of photon orbits, the innermost stable circular orbit (ISCO), and the event horizon. We find the expressions for specific energy and angular momentum for massive particles in time-like geodesics around DDM BH and investigate their dependence on DDM parameters. We display BH shadows for various values of core density and radius that reveal larger shadows cast by a \s BH surrounded by DDM (SDDM) than a \s BH in vacuum (SV). We then move on to study quasinormal modes (QNMs) with the help of the $6th$ order WKB method, the greybody factor using the semi-analytic bounds method, and the Hawking spectrum for scalar and electromagnetic perturbations. Core density and radius are found to have a significant impact on QNMs. Since QNMs for scalar and electromagnetic perturbations differ significantly, we can differentiate the two based on QNM observation. The greybody factor increases with core density and radius, whereas, the power emitted as Hawking radiation is adversely impacted by the presence of DM. We then study the weak gravitational lensing using the Gauss-Bonnet theorem and obtain the deflection angle with higher-order correction terms. Here, we see the deflection angle gets enhanced due to DM. Finally, we use bounds on the deviation from \s, $\delta$, reported by EHT for $M87^*$, Keck, and VLTI observatories for $Sgr A^*$ to gauge the viability of our model. Our model is found to be concordant with observations. This leads to the possibility of our galactic center being surrounded by DDM.