Timing analysis of the black-hole candidate Swift J1727.8-1613: detection of a dip-like feature in the high-energy cross spectrum
Timing analysis of the black-hole candidate Swift J1727.8-1613: detection of a dip-like feature in the high-energy cross spectrum
We present a timing analysis of observations with the Hard X-ray Modulation Telescope of the black hole X-ray transient Swift J1727.8-1613 during its 2023 outburst. We detect, for the first time in a black hole X-ray binary, a prominent dip at ∼3-15 Hz in the real part of the cross spectrum between high-energy (> 25 keV) and low-energy (< 10 keV) photons in the low hard and hard intermediate states, during which the QPO frequency rapidly increases and then stabilizes at ∼1.0-1.5 Hz. Remarkably, the real part of the cross spectrum reaches negative values at the frequencies around the minimum of the dip, which is indicative of a phase lag ranging between Ï 2 and Ï in this frequency range. We fit the power spectra and the real and imaginary parts of the cross spectra simultaneously using a multi-Lorentzian model. Among the lag models, the Gaussian phase-lag model provides a slightly better reduced Ï 2 than the constant phase-lag and constant time-lag models, while it also alleviates the degeneracy associated with those models. From the parameters of the Lorentzian that fits the dip, we estimated the size of the accretion flow, which consistently exceeds 10 000 km as the QPO frequency increases from 0.13 Hz to 2.0 Hz. Furthermore, both the energy-dependent phase-lag and fractional-rms spectra of the dip exhibit a change in trend around 15 keV, with the phase lag dropping and the rms reaching a local minimum. These spectra closely resemble the shapes predicted by the time-dependent Comptonization model, vKompth, for a low feedback factor, offering a pathway to explain the radiative properties of the corona. Additionally, the coherence function suggests a diversity of variability components potentially arising from different parts of the corona.
astro-ph.HE, Stars: individual: Swift J1727.8-1613, Accretion, X-rays: binaries, Stars: black holes, Accretion disks
Jin, Pei
d14c49e7-e16f-401c-8cc8-1206cd5e85e1
Méndez, Mariano
6e8725b8-553d-4b61-b839-e9585db48947
García, Federico
7c0fed66-dda4-4333-b38c-175f570820ce
Altamirano, Diego
d5ccdb09-0b71-4303-9538-05b467be075b
Zhang, Guobao
4b081922-0f52-4a4d-8d51-dea291211180
Rout, Sandeep K.
ceacfc52-c4c3-4a8b-be1a-42d4b048654d
25 June 2025
Jin, Pei
d14c49e7-e16f-401c-8cc8-1206cd5e85e1
Méndez, Mariano
6e8725b8-553d-4b61-b839-e9585db48947
García, Federico
7c0fed66-dda4-4333-b38c-175f570820ce
Altamirano, Diego
d5ccdb09-0b71-4303-9538-05b467be075b
Zhang, Guobao
4b081922-0f52-4a4d-8d51-dea291211180
Rout, Sandeep K.
ceacfc52-c4c3-4a8b-be1a-42d4b048654d
Jin, Pei, Méndez, Mariano, García, Federico, Altamirano, Diego, Zhang, Guobao and Rout, Sandeep K.
(2025)
Timing analysis of the black-hole candidate Swift J1727.8-1613: detection of a dip-like feature in the high-energy cross spectrum.
A&A, 699, [A9].
(doi:10.1051/0004-6361/202554353).
Abstract
We present a timing analysis of observations with the Hard X-ray Modulation Telescope of the black hole X-ray transient Swift J1727.8-1613 during its 2023 outburst. We detect, for the first time in a black hole X-ray binary, a prominent dip at ∼3-15 Hz in the real part of the cross spectrum between high-energy (> 25 keV) and low-energy (< 10 keV) photons in the low hard and hard intermediate states, during which the QPO frequency rapidly increases and then stabilizes at ∼1.0-1.5 Hz. Remarkably, the real part of the cross spectrum reaches negative values at the frequencies around the minimum of the dip, which is indicative of a phase lag ranging between Ï 2 and Ï in this frequency range. We fit the power spectra and the real and imaginary parts of the cross spectra simultaneously using a multi-Lorentzian model. Among the lag models, the Gaussian phase-lag model provides a slightly better reduced Ï 2 than the constant phase-lag and constant time-lag models, while it also alleviates the degeneracy associated with those models. From the parameters of the Lorentzian that fits the dip, we estimated the size of the accretion flow, which consistently exceeds 10 000 km as the QPO frequency increases from 0.13 Hz to 2.0 Hz. Furthermore, both the energy-dependent phase-lag and fractional-rms spectra of the dip exhibit a change in trend around 15 keV, with the phase lag dropping and the rms reaching a local minimum. These spectra closely resemble the shapes predicted by the time-dependent Comptonization model, vKompth, for a low feedback factor, offering a pathway to explain the radiative properties of the corona. Additionally, the coherence function suggests a diversity of variability components potentially arising from different parts of the corona.
Text
2504.20717v1
- Author's Original
Text
aa54353-25
- Version of Record
More information
Accepted/In Press date: 28 April 2025
Published date: 25 June 2025
Keywords:
astro-ph.HE, Stars: individual: Swift J1727.8-1613, Accretion, X-rays: binaries, Stars: black holes, Accretion disks
Identifiers
Local EPrints ID: 505067
URI: http://eprints.soton.ac.uk/id/eprint/505067
ISSN: 0004-6361
PURE UUID: 27cf3e2e-a6a1-432d-9aaf-814304c1ca66
Catalogue record
Date deposited: 25 Sep 2025 17:01
Last modified: 26 Sep 2025 01:50
Export record
Altmetrics
Contributors
Author:
Pei Jin
Author:
Mariano Méndez
Author:
Federico García
Author:
Guobao Zhang
Author:
Sandeep K. Rout
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
