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Main Authors: Yfantis, A. I., Palumbo, D. C. M., Mościbrodzka, M.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.16218
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author Yfantis, A. I.
Palumbo, D. C. M.
Mościbrodzka, M.
author_facet Yfantis, A. I.
Palumbo, D. C. M.
Mościbrodzka, M.
contents Sagittarius A* (Sgr A*) exhibits frequent flaring activity across the electromagnetic spectrum, often associated with a localized region of strong emission, known as a hot spot. We aim to establish an empirical relationship linking key parameters of this phenomenon -- emission radius, inclination, and black hole spin -- to the observed angle difference between the primary and secondary image ($ΔPA$) that an interferometric array could resolve. Using the numerical radiative transfer code IPOLE, we generated a library of more than 900 models with varying system parameters and computed the position angle difference on the sky between the primary and secondary images of the hot spot. We find that the average $ΔPA$ over a full period is insensitive to inclination. This result significantly simplifies potential spin measurements which might otherwise have large dependencies on inclination. Additionally, we derive a relation connecting spin to $ΔPA$, given the period and emission radius of the hot spot, with an accuracy of less than $5^\circ$ in most cases. Finally, we present a mock observation to showcase the potential of this relation for spin inference. Our results provide a novel approach for black hole spin measurements using high-resolution observations, such as future movies of Sgr A* obtained with the Event Horizon Telescope, next-generation Event Horizon Telescope, and Black Hole Explorer.
format Preprint
id arxiv_https___arxiv_org_abs_2504_16218
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Lensing of hot spots in Kerr spacetime: An empirical relation for black hole spin estimation
Yfantis, A. I.
Palumbo, D. C. M.
Mościbrodzka, M.
High Energy Astrophysical Phenomena
Sagittarius A* (Sgr A*) exhibits frequent flaring activity across the electromagnetic spectrum, often associated with a localized region of strong emission, known as a hot spot. We aim to establish an empirical relationship linking key parameters of this phenomenon -- emission radius, inclination, and black hole spin -- to the observed angle difference between the primary and secondary image ($ΔPA$) that an interferometric array could resolve. Using the numerical radiative transfer code IPOLE, we generated a library of more than 900 models with varying system parameters and computed the position angle difference on the sky between the primary and secondary images of the hot spot. We find that the average $ΔPA$ over a full period is insensitive to inclination. This result significantly simplifies potential spin measurements which might otherwise have large dependencies on inclination. Additionally, we derive a relation connecting spin to $ΔPA$, given the period and emission radius of the hot spot, with an accuracy of less than $5^\circ$ in most cases. Finally, we present a mock observation to showcase the potential of this relation for spin inference. Our results provide a novel approach for black hole spin measurements using high-resolution observations, such as future movies of Sgr A* obtained with the Event Horizon Telescope, next-generation Event Horizon Telescope, and Black Hole Explorer.
title Lensing of hot spots in Kerr spacetime: An empirical relation for black hole spin estimation
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2504.16218