Observational appearances of an inner extremal regular black hole illuminated by various accretion flows

TL;DR

This study explores how various accretion flows influence the observational signatures of an inner extremal regular black hole, highlighting the effects of quantum gravity on features like shadow size and intensity.

Contribution

It introduces a detailed analysis of accretion flow effects on regular black hole images, emphasizing quantum gravity's role in observable features.

Findings

Quantum effects significantly alter shadow radius and intensity.

Radially infalling accretion flows enhance observational differences.

Doppler effects create darker central regions in images.

Abstract

This paper investigates the observational appearances of an inner extremal regular black hole(IERBH) illuminated by various types of accretion models. The study reveals that when the BH is illuminated by specific accretion flows, the effects of quantum gravity become more pronounced,significantly impacting key observational features such as the shadow radius, photon ring, and total observed intensity. Specifically, the introduction of a more realistic radially infalling spherical accretion flow further accentuates these differences. This dynamic flow results in a darker central region in the BH image due to the Doppler effect, which modulates the observed intensity based on the relative motion of the infalling matter. The shadow radius and total observed intensity are notably affected by the quantum correction parameters, providing additional signatures that distinguish regular BHs from their classical counterparts.