Toward More Accurate Synthetic Reflection Spectra: Improving the Calculations of Returning Radiation

Mirzaev, Temurbek; Riaz, Shafqat; Abdikamalov, Askar B.; Bambi, Cosimo; Dauser, Thomas; Garcia, Javier A.; Jiang, Jiachen; Liu, Honghui; Shashank, Swarnim

doi:10.3847/1538-4357/ad303b

ApJ

2024

DOI: 10.3847/1538-4357/ad303b

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Toward More Accurate Synthetic Reflection Spectra: Improving the Calculations of Returning Radiation

Temurbek Mirzaev,

Shafqat Riaz,

Askar B. Abdikamalov

et al.

Abstract: We present a new model to calculate reflection spectra of thin accretion disks in Kerr spacetimes. Our model includes the effect of returning radiation, which is the radiation that is emitted by the disk and returns to the disk because of the strong light bending near a black hole. The major improvement with respect to the existing models is that it calculates the reflection spectrum at every point on the disk by using the actual spectrum of the incident radiation. Assuming a lamppost coronal geometry, we simu… Show more

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Cited by 3 publications

References 49 publications

(71 reference statements)

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A Tutorial on the Strong Gravity Effects in Black Hole X-Ray Spectra

Bambi

2024

Universe

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This is a tutorial on the strong gravity effects (motion of massive and massless particles in a curved spacetime, evaluation of redshift factors, estimate of physical quantities in different reference frames, etc.) necessary to calculate the electromagnetic spectra of geometrically thin and optically thick accretion disks around black holes. The presentation is intentionally pedagogical, and most calculations are reported step by step. In the disk–corona model, the spectrum of a source has three components: a thermal component from the disk, a Comptonized component from the corona, and a reflection component from the disk. This tutorial reviews only the strong gravity effects, which can be decoupled from the physical processes involving the interaction between matter and radiation. The formulas presented here are valid for stationary, axisymmetric, asymptotically flat, circular spacetimes, so they can be potentially used for a large class of black hole solutions.

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A Tutorial on the Strong Gravity Effects in Black Hole X-Ray Spectra

Bambi

2024

Universe

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Modeling Multiple X-Ray Reflection in Super-Eddington Winds

Zhang 张,

Thomsen,

Dai

et al. 2024

ApJ

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It has been recently discovered that a few super-Eddington sources undergoing black hole super-Eddington accretion exhibit X-ray reflection signatures. In such new systems, one expects the coronal X-ray emissions to be mainly reflected by optically thick super-Eddington winds instead of thin disks. In this paper, we conduct a series of general-relativistic ray-tracing and Monte Carlo radiative transfer simulations to model the X-ray reflection signatures, especially the characteristic Fe Kα line, produced from super-Eddington accretion flows around nonspinning black holes. In particular, we allow the photons emitted by a lamppost corona to be reflected multiple times in a cone-like funnel surrounded by fast winds. We find that the Fe Kα line profile most sensitively depends on the wind kinematics, while its exact shape also depends on the funnel open angle and corona height. Furthermore, very interestingly, we find that the Fe Kα line can have a prominent double-peak profile in certain parameter spaces, even with a face-on orientation. Moreover, we compare the Fe Kα line profiles produced from super-Eddington and thin disks and show that such lines can provide important insights into the understanding of black hole systems undergoing super-Eddington accretion.

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X-Ray Spectra of Black Hole X-Ray Binaries with Returning Radiation

Mirzaev,

Bambi,

Abdikamalov

et al. 2024

ApJ

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In the disk–corona model, the X-ray spectrum of a stellar-mass black hole in an X-ray binary is characterized by three components: a thermal component from a thin and cold accretion disk, a Comptonized component from a hot corona, and a reflection component produced by illumination of the cold disk by the hot corona. In this paper, we assume a lamppost corona, and we improve previous calculations of the X-ray spectrum of black hole X-ray binaries. The reflection spectrum is produced by the direct radiation from the corona as well as by the returning radiation of the thermal and reflection components and is calculated considering the actual spectrum illuminating the disk. If we turn the corona off, the reflection spectrum is completely generated by the returning radiation of the thermal component, as it may happen for some sources in soft spectral states. After choosing the radial density profile of the accretion disk, the ionization parameter is calculated self-consistently at any radial coordinate of the disk from the illuminating X-ray flux and the local electron density. We show the predictions of our model in different regimes, and we discuss its current limitations as well as the next steps to improve it.

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Toward More Accurate Synthetic Reflection Spectra: Improving the Calculations of Returning Radiation

Cited by 3 publications

References 49 publications

A Tutorial on the Strong Gravity Effects in Black Hole X-Ray Spectra

A Tutorial on the Strong Gravity Effects in Black Hole X-Ray Spectra

Modeling Multiple X-Ray Reflection in Super-Eddington Winds

X-Ray Spectra of Black Hole X-Ray Binaries with Returning Radiation

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