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Main Authors: Liu, Rongrong, Nagele, Chris, Krolik, Julian H, Kinch, Brooks E, Schnittman, Jeremy
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.01984
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author Liu, Rongrong
Nagele, Chris
Krolik, Julian H
Kinch, Brooks E
Schnittman, Jeremy
author_facet Liu, Rongrong
Nagele, Chris
Krolik, Julian H
Kinch, Brooks E
Schnittman, Jeremy
contents Data derived from general relativistic magnetohydrodynamic simulations of accretion onto black holes can be used as input to a postprocessing scheme that predicts the radiated spectrum. Combining a relativistic Compton scattering radiation transfer solution in the corona with detailed local atmosphere solutions incorporating local ionization and thermal balance within the disk photosphere, it is possible to study both spectral formation and intrinsic spectral variability in the radiation from relativistic accretion disks. With this method, we find that radiatively efficient systems with black holes of $10M_\odot$ accreting at $\approx 0.01$ in Eddington units produce spectra very similar to those observed in the hard states of X-ray binaries. The spectral shape above 10keV is well described by a power law with an exponential cutoff. Intrinsic turbulent variations lead to order-unity changes in bolometric luminosity, variations in the logarithmic spectral slope $\sim 0.1$, and factor of 2 alterations in the cutoff energy on timescales $\sim 50(M_{\rm BH}/10 M_\odot)$ms. Within the corona, the range of gas temperature spans more than 1 order of magnitude. The wide distribution of temperatures is central to defining the spectrum: the logarithmic spectral slope is harder by $\sim 0.3$ and the cutoff energy larger by a factor $\sim 10 - 30$ than if the coronal temperature everywhere were its mass-weighted mean.
format Preprint
id arxiv_https___arxiv_org_abs_2412_01984
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Simulation-Based Prediction of Black Hole X-ray Spectra and Spectral Variability
Liu, Rongrong
Nagele, Chris
Krolik, Julian H
Kinch, Brooks E
Schnittman, Jeremy
High Energy Astrophysical Phenomena
Data derived from general relativistic magnetohydrodynamic simulations of accretion onto black holes can be used as input to a postprocessing scheme that predicts the radiated spectrum. Combining a relativistic Compton scattering radiation transfer solution in the corona with detailed local atmosphere solutions incorporating local ionization and thermal balance within the disk photosphere, it is possible to study both spectral formation and intrinsic spectral variability in the radiation from relativistic accretion disks. With this method, we find that radiatively efficient systems with black holes of $10M_\odot$ accreting at $\approx 0.01$ in Eddington units produce spectra very similar to those observed in the hard states of X-ray binaries. The spectral shape above 10keV is well described by a power law with an exponential cutoff. Intrinsic turbulent variations lead to order-unity changes in bolometric luminosity, variations in the logarithmic spectral slope $\sim 0.1$, and factor of 2 alterations in the cutoff energy on timescales $\sim 50(M_{\rm BH}/10 M_\odot)$ms. Within the corona, the range of gas temperature spans more than 1 order of magnitude. The wide distribution of temperatures is central to defining the spectrum: the logarithmic spectral slope is harder by $\sim 0.3$ and the cutoff energy larger by a factor $\sim 10 - 30$ than if the coronal temperature everywhere were its mass-weighted mean.
title Simulation-Based Prediction of Black Hole X-ray Spectra and Spectral Variability
topic High Energy Astrophysical Phenomena
url https://arxiv.org/abs/2412.01984