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Main Authors: Porter, Kaitlyn, Noble, Scott C., Gutierrez, Eduardo M., Pelle, Joaquin, Campanelli, Manuela, Schnittman, Jeremy, Kelly, Bernard J.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.04089
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author Porter, Kaitlyn
Noble, Scott C.
Gutierrez, Eduardo M.
Pelle, Joaquin
Campanelli, Manuela
Schnittman, Jeremy
Kelly, Bernard J.
author_facet Porter, Kaitlyn
Noble, Scott C.
Gutierrez, Eduardo M.
Pelle, Joaquin
Campanelli, Manuela
Schnittman, Jeremy
Kelly, Bernard J.
contents Supermassive black holes (SMBHs) are thought to be located at the centers of most galactic nuclei. When galaxies merge they form supermassive black hole binary (SMBHB) systems and these central SMBHs will also merge at later times, producing gravitational waves (GWs). Because galaxy mergers are likely gas-rich environments, SMBHBs are also potential sources of electromagnetic (EM) radiation. The EM signatures depend on gas dynamics, orbital dynamics, and radiation processes. The gas dynamics are governed by general relativistic magnetohydrodynamics (MHD) in a time-dependent spacetime. Numerically solving the MHD equations for a time-dependent binary spacetime is computationally expensive. Therefore, it is challenging to conduct a full exploration of the parameter space of these systems and the resulting EM signatures. We have developed an analytical accretion disk model for the mini-disks of an SMBHB system and produced images and light curves using a general relativistic ray-tracing code and a superimposed harmonic binary black hole metric. This analytical model greatly reduces the time and computational resources needed to explore these systems, while incorporating some key information from simulations. We present a parameter space exploration of the SMBHB system in which we have studied the dependence of the EM signatures on the spins of the black holes (BHs), the mass ratio, the accretion rate, the viewing angle, and the initial binary separation. Additionally, we study how the commonly used fast-light approximation affects the EM signatures and evaluate its validity in GRMHD simulations.
format Preprint
id arxiv_https___arxiv_org_abs_2407_04089
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A Parameter Study of the Electromagnetic Signatures of an Analytical Mini-Disk Model for Supermassive Binary Black Hole Systems
Porter, Kaitlyn
Noble, Scott C.
Gutierrez, Eduardo M.
Pelle, Joaquin
Campanelli, Manuela
Schnittman, Jeremy
Kelly, Bernard J.
High Energy Astrophysical Phenomena
Supermassive black holes (SMBHs) are thought to be located at the centers of most galactic nuclei. When galaxies merge they form supermassive black hole binary (SMBHB) systems and these central SMBHs will also merge at later times, producing gravitational waves (GWs). Because galaxy mergers are likely gas-rich environments, SMBHBs are also potential sources of electromagnetic (EM) radiation. The EM signatures depend on gas dynamics, orbital dynamics, and radiation processes. The gas dynamics are governed by general relativistic magnetohydrodynamics (MHD) in a time-dependent spacetime. Numerically solving the MHD equations for a time-dependent binary spacetime is computationally expensive. Therefore, it is challenging to conduct a full exploration of the parameter space of these systems and the resulting EM signatures. We have developed an analytical accretion disk model for the mini-disks of an SMBHB system and produced images and light curves using a general relativistic ray-tracing code and a superimposed harmonic binary black hole metric. This analytical model greatly reduces the time and computational resources needed to explore these systems, while incorporating some key information from simulations. We present a parameter space exploration of the SMBHB system in which we have studied the dependence of the EM signatures on the spins of the black holes (BHs), the mass ratio, the accretion rate, the viewing angle, and the initial binary separation. Additionally, we study how the commonly used fast-light approximation affects the EM signatures and evaluate its validity in GRMHD simulations.
title A Parameter Study of the Electromagnetic Signatures of an Analytical Mini-Disk Model for Supermassive Binary Black Hole Systems
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2407.04089