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X-ray eclipse mapping constrains the binary inclination and mass ratio of swift J1858.6-0814

X-ray eclipse mapping constrains the binary inclination and mass ratio of swift J1858.6-0814
X-ray eclipse mapping constrains the binary inclination and mass ratio of swift J1858.6-0814
X-ray eclipse mapping is a promising modelling technique, capable of constraining the mass and/or radius of neutron stars (NSs) or blackholes (BHs) in eclipsing binaries and probing any structure surrounding the companion star. In eclipsing systems, the binary inclination, $i$, and mass ratio, $q$ relate via the duration of totality, $t_{e}$. The degeneracy between $i$ and $q$ can then be broken through detailed modelling of the eclipse profile. Here we model the eclipses of the NS low-mass X-ray binary Swift J1858.6$-$0814 utilising archival NICER observations taken while the source was in outburst. Analogous to EXO0748$-$676, we find evidence for irradiation driven ablation of the companion's surface by requiring a layer of stellar material to surround the companion star in our modelling. This material layer extends $\sim7000 - 14000$ km from the companion's surface and is likely the cause of the extended, energy-dependent and asymmetric ingress and egress that we observe. Our fits return an inclination of $i \sim 81^{\circ}$ and a mass ratio $q \sim 0.14$. Using Kepler's law to relate the mass and radius of the companion star via the orbital period ($\sim$ 21.3 hrs), we subsequently determine the companion to have a low mass in the range $0.183 M_{\odot} \leq M_{cs} \leq 0.372 M_{\odot}$ and a large radius in the range $1.02 R_{\odot} \leq R_{cs} \leq 1.29 R_{\odot}$. Our results, combined with future radial velocity amplitudes measured from stellar absorption/emission lines, can place precise constraints on the component masses in this system.
Astrophysics - High Energy Astrophysical Phenomena
1908 - 1920
Knight, Amy H.
394b1ae4-038f-43d2-bb70-96d030ef2c6e
Ingram, Adam
01a02529-ad9f-4936-af5d-c200f88d4e53
Middleton, Matthew
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Knight, Amy H.
394b1ae4-038f-43d2-bb70-96d030ef2c6e
Ingram, Adam
01a02529-ad9f-4936-af5d-c200f88d4e53
Middleton, Matthew
f91b89d9-fd2e-42ec-aa99-1249f08a52ad

Knight, Amy H., Ingram, Adam and Middleton, Matthew (2022) X-ray eclipse mapping constrains the binary inclination and mass ratio of swift J1858.6-0814. Monthly Notice of the Royal Astronomical Society, 514 (2), 1908 - 1920.

Record type: Article

Abstract

X-ray eclipse mapping is a promising modelling technique, capable of constraining the mass and/or radius of neutron stars (NSs) or blackholes (BHs) in eclipsing binaries and probing any structure surrounding the companion star. In eclipsing systems, the binary inclination, $i$, and mass ratio, $q$ relate via the duration of totality, $t_{e}$. The degeneracy between $i$ and $q$ can then be broken through detailed modelling of the eclipse profile. Here we model the eclipses of the NS low-mass X-ray binary Swift J1858.6$-$0814 utilising archival NICER observations taken while the source was in outburst. Analogous to EXO0748$-$676, we find evidence for irradiation driven ablation of the companion's surface by requiring a layer of stellar material to surround the companion star in our modelling. This material layer extends $\sim7000 - 14000$ km from the companion's surface and is likely the cause of the extended, energy-dependent and asymmetric ingress and egress that we observe. Our fits return an inclination of $i \sim 81^{\circ}$ and a mass ratio $q \sim 0.14$. Using Kepler's law to relate the mass and radius of the companion star via the orbital period ($\sim$ 21.3 hrs), we subsequently determine the companion to have a low mass in the range $0.183 M_{\odot} \leq M_{cs} \leq 0.372 M_{\odot}$ and a large radius in the range $1.02 R_{\odot} \leq R_{cs} \leq 1.29 R_{\odot}$. Our results, combined with future radial velocity amplitudes measured from stellar absorption/emission lines, can place precise constraints on the component masses in this system.

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Accepted/In Press date: 9 May 2022
e-pub ahead of print date: 13 May 2022
Keywords: Astrophysics - High Energy Astrophysical Phenomena

Identifiers

Local EPrints ID: 471940
URI: http://eprints.soton.ac.uk/id/eprint/471940
PURE UUID: 7fbf7523-bd6e-47ca-98af-bae7f898b18d

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Date deposited: 22 Nov 2022 17:59
Last modified: 16 Mar 2024 22:54

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Contributors

Author: Amy H. Knight
Author: Adam Ingram
Author: Matthew Middleton

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