Time-resolved UV spectroscopy of the accretion disk and wind in a super-Eddington black-hole X-ray transient
Time-resolved UV spectroscopy of the accretion disk and wind in a super-Eddington black-hole X-ray transient
In October 2018, Swift announced the discovery of a new Galactic X-ray transient, Swift J1858. Just before Sun-angle constraints rendered the system unobservable, follow-up observations revealed extreme flaring activity, of a kind that has so far only been seen in the famous black hole X-ray binary (BHXRB) V404 Cyg during its 2015 eruption and in V4641 Sgr. The peculiar behaviour of these sources is thought to be a consequence of super-Eddington accretion regime. After several months of unusual strong and rapid flaring in its high-luminosity state, Swift J1858 is currently exhibiting impressive optical P-Cygni profiles, suggesting the pres- ence of a dense and cool wind from the outer accretion disk. The dominant spectroscopic signatures of such winds are actually expected to lie in the far-ultraviolet region, but they are usually inaccessible in black-hole X-ray binaries, due to interstellar reddening. Given its low extinction, Swift J1858 provides us with a rare chance to study the accretion disk wind in the crucial ultraviolet band - an opportunity that was missed in the other two systems. Building on an ongoing multi-wavelength campaign (X-rays: NICER; optical: GTC; radio: VLA & AMI), we therefore request far- and near-UV time-resolved spectroscopic observations of this system with HST/STIS+COS in order to (a) study its extreme accretion disk wind; (b) test proposed wind driving mechanisms; (c) characterize its UV variability properties and determine the origin of these variations; (d) construct the broad-band SED of the outer accretion disk that dominates the UV flux; and (e) determine the extinction towards the system in order to constrain the mass accretion rate.
Space Telescope Science Institute
Castro Segura, Noel
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Knigge, Christian
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Altamirano, Diego
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Gandhi, Poshak
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Charles, Philip A.
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Middleton, Matthew
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Paice, John
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July 2019
Castro Segura, Noel
0dee6349-38d9-4a0e-b389-df77063638d5
Knigge, Christian
ac320eec-631a-426e-b2db-717c8bf7857e
Altamirano, Diego
d5ccdb09-0b71-4303-9538-05b467be075b
Gandhi, Poshak
5bc3b5af-42b0-4dd8-8f1f-f74048d4d4a9
Charles, Philip A.
0429b380-0754-4dc1-8def-885c7fa6a086
Middleton, Matthew
f91b89d9-fd2e-42ec-aa99-1249f08a52ad
Paice, John
8ac21dae-fc44-4797-b2aa-31125c9172ae
Castro Segura, Noel, Knigge, Christian and Altamirano, Diego
,
et al.
(2019)
Time-resolved UV spectroscopy of the accretion disk and wind in a super-Eddington black-hole X-ray transient.
Abstract
In October 2018, Swift announced the discovery of a new Galactic X-ray transient, Swift J1858. Just before Sun-angle constraints rendered the system unobservable, follow-up observations revealed extreme flaring activity, of a kind that has so far only been seen in the famous black hole X-ray binary (BHXRB) V404 Cyg during its 2015 eruption and in V4641 Sgr. The peculiar behaviour of these sources is thought to be a consequence of super-Eddington accretion regime. After several months of unusual strong and rapid flaring in its high-luminosity state, Swift J1858 is currently exhibiting impressive optical P-Cygni profiles, suggesting the pres- ence of a dense and cool wind from the outer accretion disk. The dominant spectroscopic signatures of such winds are actually expected to lie in the far-ultraviolet region, but they are usually inaccessible in black-hole X-ray binaries, due to interstellar reddening. Given its low extinction, Swift J1858 provides us with a rare chance to study the accretion disk wind in the crucial ultraviolet band - an opportunity that was missed in the other two systems. Building on an ongoing multi-wavelength campaign (X-rays: NICER; optical: GTC; radio: VLA & AMI), we therefore request far- and near-UV time-resolved spectroscopic observations of this system with HST/STIS+COS in order to (a) study its extreme accretion disk wind; (b) test proposed wind driving mechanisms; (c) characterize its UV variability properties and determine the origin of these variations; (d) construct the broad-band SED of the outer accretion disk that dominates the UV flux; and (e) determine the extinction towards the system in order to constrain the mass accretion rate.
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Published date: July 2019
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Local EPrints ID: 486493
URI: http://eprints.soton.ac.uk/id/eprint/486493
PURE UUID: 93f482f0-757d-4170-aafc-840e63d72e90
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Date deposited: 24 Jan 2024 17:44
Last modified: 18 Mar 2024 03:31
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Author:
Noel Castro Segura
Author:
Mehtap Ozbey Arabaci
Author:
John Paice
Corporate Author: et al.
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