An empirical connection between line-emitting regions and X-rays heating the accretion disc in BH-LMXB MAXI J1820+070
An empirical connection between line-emitting regions and X-rays heating the accretion disc in BH-LMXB MAXI J1820+070
The recurring transient outbursts in low-mass X-ray binaries (LMXBs) provide ideal laboratories to study the accretion process. Unlike their supermassive relatives, LMXBs are far too small and distant to be imaged directly. Fortunately, phase-resolved spectroscopy can provide an alternative diagnostic to study their highly complex, time-dependent accretion discs. The primary spectral signature of LMXBs are strong, disc-formed emission lines detected at optical wavelengths. The shape, profile, and appearance/disappearance of these lines change throughout a binary orbit, and thus, can be used to trace how matter in these discs behaves and evolves over time. By combining a \textit{Swift} multi-wavelength monitoring campaign, phase-resolved spectroscopy from the Gran Telescopio Canarias (GTC) and Liverpool Telescope, and modern astrotomography techniques, we find a clear empirical connection between the line emitting regions and physical properties of the X-rays heating the disc in the black hole LMXB MAXI J1820+070 during its 2018 outburst. In this paper, we show how these empirical correlations can be used as an effective observational tool for understanding the geometry and structure of a LMXB accretion disc and present further evidence for an irradiation-driven warped accretion disc present in this system.
astro-ph.HE
Tetarenko, B.E.
b62ce163-46fb-4989-b805-b6b2b5a78121
Shaw, A.W.
ec4ee525-bcb1-4f0a-aa13-2f3f42b6bfb0
Charles, P.A.
0429b380-0754-4dc1-8def-885c7fa6a086
Tetarenko, B.E.
b62ce163-46fb-4989-b805-b6b2b5a78121
Shaw, A.W.
ec4ee525-bcb1-4f0a-aa13-2f3f42b6bfb0
Charles, P.A.
0429b380-0754-4dc1-8def-885c7fa6a086
[Unknown type: UNSPECIFIED]
Abstract
The recurring transient outbursts in low-mass X-ray binaries (LMXBs) provide ideal laboratories to study the accretion process. Unlike their supermassive relatives, LMXBs are far too small and distant to be imaged directly. Fortunately, phase-resolved spectroscopy can provide an alternative diagnostic to study their highly complex, time-dependent accretion discs. The primary spectral signature of LMXBs are strong, disc-formed emission lines detected at optical wavelengths. The shape, profile, and appearance/disappearance of these lines change throughout a binary orbit, and thus, can be used to trace how matter in these discs behaves and evolves over time. By combining a \textit{Swift} multi-wavelength monitoring campaign, phase-resolved spectroscopy from the Gran Telescopio Canarias (GTC) and Liverpool Telescope, and modern astrotomography techniques, we find a clear empirical connection between the line emitting regions and physical properties of the X-rays heating the disc in the black hole LMXB MAXI J1820+070 during its 2018 outburst. In this paper, we show how these empirical correlations can be used as an effective observational tool for understanding the geometry and structure of a LMXB accretion disc and present further evidence for an irradiation-driven warped accretion disc present in this system.
Text
2310.11438v1
- Author's Original
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Accepted/In Press date: 17 October 2023
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7 figures, accepted for publication in MNRAS
Keywords:
astro-ph.HE
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Local EPrints ID: 484329
URI: http://eprints.soton.ac.uk/id/eprint/484329
PURE UUID: cdf0c163-af79-4219-b0b2-b31478e7292c
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Date deposited: 15 Nov 2023 18:10
Last modified: 17 Mar 2024 05:44
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Author:
B.E. Tetarenko
Author:
A.W. Shaw
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